Reaction mechanism of succinyl CoA synthetase from pigeon thoracic muscle

The ability of succinyl-CoA-synthetase from pigeon thoracic muscle to interact with ATP is investigated. gamma-32P-ATP and 8-14C-ATP were used in experiments. It is found that the enzyme, when reacting with ATP in the presence of Mg2+, forms a complex containing 2 moles of ATP residue and 2 moles of phosphoric acid residue (splitted from ATP) per 1 mole of protein. After 2 hours of incubation at 0-4 degrees C, the complex is converted into another one, containing 4 residues of phosphoric acid per 1 mole of @protein. Both complexes are active, and their incubation with succinate and CoA results in the formation of succinyl-CoA. The reaction capacity of these enzyme complexes with some reaction substrates is investigated. The enzyme complex containing 2 phosphoric acid residues and 2 nucleotide residues is found to interact neither with CoA, nor with succinate. The enzyme complex containing 4 phosphoric acid residues does not react with CoA, but it interacts with 14C-succinate, releasing inorganic phosphate in the amount equivalent to the equimolar amount of protein-binding succinic acid.     

Porphyrin biosynthesis: immobilized enzymes and ligands. VI. Studies on succinyl CoA synthetase from cultured soya bean cells

Soybean callus succinyl CoA synthetase (succinate: CoA ligase, (ADP-forming), EC 6.2.1.5), has been chemically bound to Sepharose 4B and some of its properties have been studied. The optimal conditions for binding have been determined. The immobilized enzyme retained 48% of the activity of the soluble enzyme and the coupling yield amounted to 50%. Sepharose-succinyl CoA synthetase can be stored at 4 degrees C for periods up to 90 days with only 25% loss of activity; it can also be repeatedly used without alteration of its enzymic activity. The complex showed enhanced thermal stability; pH optimum was between 7.0 and 8.0 for the bound enzyme, and 8.0 for the free enzyme. A general decrease in the Michaelis-Menten constants for the different substrates of the insoluble enzyme, as compared with values obtained for the free enzyme, was found. Plots of the rate product formation against ATP concentration changed from sigmoideal for the soluble succinyl CoA synthetase to hyperbolic for the immobilized enzyme.     

Mechanism of action of Escherichia coli phosphoribosylaminoimidazolesuccinocarboxamide synthetase

The conversion of ATP, L-aspartate, and 5-aminoimidazole-4-carboxyribonucleotide (CAIR) to 5-aminoimidazole-4-(N-succinylcarboxamide) ribonucleotide (SAICAR), ADP, and phosphate by phosphoribosylaminoimidazolesuccinocarboxamide synthetase (SAICAR synthetase) represents the eighth step of de novo purine nucleotide biosynthesis. SAICAR synthetase and other enzymes of purine biosynthesis are targets of natural products that impair cell growth. Prior to this study, no kinetic mechanism was known for any SAICAR synthetase. Here, a rapid equilibrium random ter-ter kinetic mechanism is established for the synthetase from Escherichia coli by initial velocity kinetics and patterns of linear inhibition by IMP, adenosine 5'-(beta,gamma-imido)triphosphate (AMP-PNP), and maleate. Substrates exhibit mutual binding antagonism, with the strongest antagonism between CAIR and either ATP or L-aspartate. CAIR binds to the free enzyme up to 200-fold more tightly than to the ternary enzyme-ATP-aspartate complex, but the latter complex may be the dominant form of SAICAR synthetase in vivo. IMP is a competitive inhibitor with respect to CAIR, suggesting the possibility of a hydrogen bond interaction between the 4-carboxyl and 5-amino groups of enzyme-bound CAIR. Of several aspartate analogues tested (hadacidin, l-malate, succinate, fumarate, and maleate), maleate was by far the best inhibitor, competitive with respect to L-aspartate. Inhibition by IMP and maleate is consistent with a chemical mechanism for SAICAR synthetase that parallels that of adenylosuccinate synthetase.     

Erythrocyte membrane acyl:CoA synthetase activity

The presence of long-chain acyl:CoA synthetases in mammalian microsomes and mitochondria has been established previously [(1971) Biochim. Biophys. Acta 231, 32-47]. The presence of a plasma membrane-associated enzyme was investigated in human erythrocyte ghost plasma membranes, where an enzyme exhibiting high activity, and with a preferred substrate of 18 carbon chain length, was discovered. The results are consistent with the presence of a single enzyme. The effect of the degree of unsaturation of the fatty acid substrates was not as pronounced as that arising from the length of the carbon chain. The pattern of substrate preference of the enzyme was omega 3 polyenoics greater than omega 6 polyenoics greater than omega 9 monoenoics greater than saturated fatty acids. This may relate to the similar substrate preference pattern exhibited by the fatty acyl desaturase enzymes. However, the role played by long-chain acyl:CoA synthetase in erythrocyte metabolism is uncertain, but may relate to the transportation of polyenoic fatty acids in the circulation.     

Regulatory role of GDP in the phosphoenzyme formation of guanine nucleotide: Specific forms of succinyl coenzyme a synthetase

We have previously shown that micromolar concentrations of GDP stimulate the GTP-mediated phosphorylation of p36, the subunit of succinyl-CoA synthetase (SCS), in lysates prepared fromDictyostelium discoideum. In this study, we report that this phenomenon represents an enhanced catalytic capacity of SCS to form the phosphoenzyme intermediate. Low concentrations of GDP stimulate phosphoenzyme formation by either GTP, or succinyl-CoA and P_i. Under these conditions GDP enhances the apparent rate of phosphoenzyme formation but does not significantly alter the fraction of phosphorylated enzyme. This effect is retained during purification of the protein and is also observed with purified pig heart SCS, indicating that GDP directly alters the enzyme to enhance its rate of phosphorylation. Under these conditions, GDP does not function at the catalytic site, implying an allosteric regulation of SCS.Abbreviations used SCS succinyl-CoA synthetase - P _i inorganic phosphate - NDP nucleotide diphosphate - NTP nucleotide triphosphate - PFK phosphofructokinase A-form; ADP-forming SCS; G-form; GDP-forming SCS