Pyruvate phosphate dikinase: Difference between revisions
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The enzyme has been found in bacteria, in C<sub>4</sub> and Crassulacean acid metabolism plants, and in parasites, but not in higher animal forms. In bacteria and parasites, PPDK functions in the direction of ATP synthesis (reminiscent of pyruvate kinase). In plants and in photosynthetic bacteria, PPDK functions in PEP formation, potentiating the rate of CO<sub>2</sub> fixation that takes place during photosynthesis.PPDK exhibits sequence homology to pyruvate phosphate synthase, and to another enzyme that utilizes phosphotransfer from PEP to a histidine residues, Enzyme I of the PEP:sugar phosphotransferase system (PTS. | The enzyme has been found in bacteria, in C<sub>4</sub> and Crassulacean acid metabolism plants, and in parasites, but not in higher animal forms. In bacteria and parasites, PPDK functions in the direction of ATP synthesis (reminiscent of pyruvate kinase). In plants and in photosynthetic bacteria, PPDK functions in PEP formation, potentiating the rate of CO<sub>2</sub> fixation that takes place during photosynthesis.PPDK exhibits sequence homology to pyruvate phosphate synthase, and to another enzyme that utilizes phosphotransfer from PEP to a histidine residues, Enzyme I of the PEP:sugar phosphotransferase system (PTS. | ||
PPDK assembles into homodimers of ~95 kD subunit molecular mass. The monomer is comprised of three domains and contains two distinct reaction centers located ~45 Å apart; the PEP/pyruvate partial reaction (step 1) takes place at the C-terminal domain (adopting an α/β barrel fold) and the nucleotide and inorganic phosphate partial reactions (steps 2 and 3) take place at the N-terminal domain (adopting the ATP grasp fold with two sub domains). A central domain, tethered to the N- and C-terminal domains by two closely-associated linkers, contains a phosphorylatable histidine residue (His455). To shuttle the phosphoryl group between the two reaction centers, the His-domain undergoes a ~110° swivel motion around the two linkers. In addition, upon detachment from the His-domain, the two nucleotide-binding sub domains undergo a ~40° hinge motion that opens the active site cleft. | |||
The movie depicts the catalytic reaction involving three in-line phosphotransfers and the accompanied protein conformational transitions. This is a model based on crystal structures of PPDK from ''Clostridium symbiosum'' in the two extreme conformational states and of complexes bound to substrate analogs, phosphonopyruvate and 5'-adenylyl-β,γ-imidodiphosphate (AMPPNP). The nucleotide binding subdomains are colored green and blue. The PEP binding domain is colored cyan. The His-domain is colored yellow, and the linker segments that connect the His-domain to the partner domains are colored red. Ligands and the catalytic histidine are depicted in stick models with the atomic color scheme: Carbon – gray, Nitrogen – blue, Oxygen – red, Phosphorous – green, Magnesium – magenta. | The movie depicts the catalytic reaction involving three in-line phosphotransfers and the accompanied protein conformational transitions. This is a model based on crystal structures of PPDK from ''Clostridium symbiosum'' in the two extreme conformational states and of complexes bound to substrate analogs, phosphonopyruvate and 5'-adenylyl-β,γ-imidodiphosphate (AMPPNP). The nucleotide binding subdomains are colored green and blue. The PEP binding domain is colored cyan. The His-domain is colored yellow, and the linker segments that connect the His-domain to the partner domains are colored red. Ligands and the catalytic histidine are depicted in stick models with the atomic color scheme: Carbon – gray, Nitrogen – blue, Oxygen – red, Phosphorous – green, Magnesium – magenta. | ||