Regulation of enzymes of purine metabolism in intact tumor cells

Purine and pyrimidine metabolism: pathways, pitfalls and perturbations

The conceptual framework which underlies many studies of purine and pyrimidine metabolism in intact cells has been critically evaluated. The model that is implicit in many such studies is the single, partially purified enzyme. This paper gives examples both of instances in which the extrapolation of results of enzymes studies to intact cells has been successful and of instances in which enzymes behave differently in the intact cell than in cell extracts. Pitfalls in the extrapolation of results of enzyme studies to intact cells concern (a) metabolic pathways, (b) intracellular enzyme activities, (c) enzyme regulation, and (d) intracellular metabolite concentrations. Examples are also given of situations in which perturbations in one aspect of purine or pyrimidine metabolism lead to changes in other aspects, often distant in the network of reactions.

Metabolism of hypoxanthine in isolated rat hepatocytes

The hepatic metabolism of hypoxanthine was investigated by studying both the fate of labelled hypoxanthine, added at micromolar concentrations to isolated rat hepatocyte suspensions, and the kinetic properties of purified hypoxanthine/guanine phosphoribosyltransferase from rat liver. More than 80% of hypoxanthine was oxidized towards allantoin; less than 5% of the label was incorporated into the purine mononucleotides, and a similar proportion appeared transiently in inosine. The maximal velocity of oxidation (approx. 750nmol/min per g of cells) was in close agreement with the known activity of xanthine oxidase in liver extracts. In contrast, the maximal velocity of the incorporation of labelled hypoxanthine into mononucleotides reached only 30nmol/min per g of cells, compared with an activity of hypoxanthine/guanine phosphoribosyltransferase, measured at substrate concentrations analogous to those prevailing intracellularly, of 500nmol/min per g of cells. Hypoxanthine incorporation into the mononucleotides was decreased by allopurinol, anoxia and ethanol, despite inhibition of its oxidation under these conditions; it was increased by incubation of the cells in supraphysiological concentrations of Pi. Allopurinol and anoxia decreased the concentration of phosphoribosyl pyrophosphate inside the cells by respectively 40 and 60%, ethanol had no effect on the concentration of this metabolite and Pi increased its concentration up to 10-fold. The kinetic study of purified hypoxanthine/guanine phosphoribosyltransferase showed that a mixture of ATP, IMP, GMP and GTP, at the concentrations prevailing in the liver cell, decreased the V max. of the enzyme 6-fold, increased its Km for hypoxanthine from 1 to 4 microM and its Km for phosphoribosyl pyrophosphate from 2.5 to 25 microM. In the presence of 5 microM-hypoxanthine and 2.5 microM-phosphoribosyl pyrophosphate, the mixture of nucleotides inhibited the activity of purified hypoxanthine/guanine phosphoribosyltransferase by 95%. It is concluded that this inhibition results in a limited participation of hypoxanthine/guanine phosphoribosyltransferase in the control of the production of allantoin by the liver.

The relationship between glutamate deamination and gluconeogenesis in kidney

The effect of 3-mercaptopicolinate, an inhibitor of phosphoenolpyruvate carboxykinase [GTP:oxaloacetate carboxy-lyase (transphosphorylating), EC 4.1.1.32], was tested on NH3 formation via the purine nucleotide cycle and glutamate dehydrogenase (EC 1.4.1.2). NH3 excretion in rats increased 70-fold after 48 h of NH4Cl feeding, from 12.2 +/- 4.5 to 862 +/- 190 mumol/mg of creatinine. At 4 h after a single intraperitoneal injection of 3-mercaptopicolinate into NH4Cl-fed rats, NH3 excretion was inhibited by 93%. Kidneys of NH4Cl-fed plus 3-mercaptopicolinate-treated rats, compared with those of NH4Cl-fed rats, showed a 3.5-fold increase in the content of IMP, 5-fold increase in adenylosuccinate, 4-fold increase in aspartate, and a 30% increase in AMP. 3-Mercaptopicolinate completely inhibited NH3 and glucose formation from glutamate in tubules from acidotic rats and NH3 formation from aspartate in kidney perfusion experiments. When transamination in tubules was prevented by 2-amino-4-methoxy-trans-but-3-enoic acid, formation of glucose, but not of NH3, from glutamate was inhibited. 3-Mercaptopicolinate completely inhibited NH3 formation from aspartate in the presence of the aminotransferase inhibitor in kidney tubules. The data show that NH3 can be formed via glutamate dehydrogenase and the purine nucleotide cycle at significant and approximately equal rates. 3-Mercaptopicolinate has no direct effect on NH3 formation via glutamate dehydrogenase, but inhibits that via the purine nucleotide cycle. We conclude that gluconeogenesis is not regulatory for NH3 formation in kidney.

Pathways of purine ribonucleotide biosynthesis in the adult worm Metastrongylus apri (Nematoda: Metastrongyloidea) from pig lung

The pathways of purine ribonucleotide synthesis and interconversion that are operative in the intact adult pig lung worm Metastrongylus apri were identified by radioisotope tracing. The rate of [14C]glycine incorporation into purines was low but sufficient to demonstrate synthesis de novo. Radioactively labelled adenine, hypoxanthine and guanine were readily taken up and converted to the corresponding mononucleotides. Most of the AMP and GMP formed were phosphorylated to the triphosphates. These two nucleotides were interconvertable by pathways in which IMP is an intermediate. Adenosine was converted to nucleotides by direct phosphorylation as well as via formation of hypoxanthine. The rate of synthesis of adenine nucleotides from hypoxanthine was 5-7 times that of guanine nucleotides; conversion of IMP to AMP and to xanthosine 5'-monophosphate were the rate-limiting steps.

The effects of added purines on urate and purine synthesis de novo by isolated chick liver, kidney and lymphoid cells

1. Isolated chick lymphoid cells, together with isolated chick liver and kidney cells, incorporate [1-14C]glycine or [14C]formate into urate. 2. Of the cell types used, bursal cells incorporate 14C into urate at the fastest rate, although the output of total urate by bursal cells is only 10% that of liver cells. 3. When suspended in Eagle's medium the incorporation of 14C into urate is inhibited by adenine and guanine up to 1 mM. In contrast, the addition of 1 mM-AMP or -GMP results in a relatively large stimulation of this incorporation. 4. Added adenine is rapidly taken up by liver cells and then released in an unmetabolized form; AMP is taken up more slowly and is rapidly metabolized. The metabolites (possibly including adenine) are then released. 5. Intracellular liver 5-phosphoribosyl 1-pyrophosphate is approx. 0.7mM and remains constant or falls slightly during a 3 h incubation of the cells. 6. The addition of adenine or guanine, AMP or GMP, does not alter liver intracellular 5-phosphoribosyl 1-pyrophosphate concentrations. Added 5-phosphoribosyl 1-pyrophosphate is not taken up by liver cells. 7. The results are discussed in the context of the control of urate and purine synthesis de novo in the chick.