The metabolism of 3-deazaguanine and 3-deazaguanosine by human cells in culture

The metabolism of the purine analogs 3-deazaguanine and 3-deazaguanosine was studied in cultured human cells using radiolabeled tracers, individual enzyme assays, and mutant cell lines. The toxicity of each drug appeared to require conversion to the 5' nucleotide. The base was converted to the nucleotide by hypoxanthine guanine phosphoribosyl transferase. The conversion of the nucleoside to the nucleotide was catalyzed by an unidentified kinase. Purine nucleoside 3-deazaguanosine-5'-monophosphate was converted to its corresponding di- and triphosphate by guanylate kinase. Both the base and the nucleoside were incorporated into DNA but not RNA.     

Characterization of analog resistance and purine metabolism of adult rat-liver epithelial cell 8-azaguanine-resistant mutants

Adult rat-liver epithelial cultures were sensitive to the lethal effects of 8-azaguanine (AG), but lines contained variants resistant to AG. The frequency of retrievable AG-resistant colonies varied with both the concentration of AG used and the seeding density of the population under selection. Cells resistant to AG were also cross-resistant to 6-thioguanine and unable to grow in medium containing hypoxanthine, aminopterin and thymidine. Resistance was stable. AG resistance was due to a deficiency of hypoxanthine-guanine phosphoribosyl transferase (HGPRTase) activity which was not caused by an inhibitor. In the assay for HGPRTase, a substantial amount of product appeared as inosine (In) in addition to inosine monophosphate (IMP). Purine nucleoside phosphorylase will generate In from hypoxanthine and, indeed, the cells did possess this activity. However, several findings indicated that the In was derived from IMP by catabolism by 5'-nucleotidase (NTase): (1) IMP decreased as In increased and (2) the inhibitors of NTase, adenosine monophosphate and thymidine triphosphate, reduced the generation of In by over 90% without inhibiting purine nucleoside phosphorylase. The cells possessed substantial NTase activity, 35% of which was located in the cytosol along with 69% of HGPRTase. Several lines of evidence suggested that the NTase activity limited the amount of 8-azaguanylic acid presented to the cells by catabolising the nucleotide and, thereby, reducing the toxicity of available AG.     

Adenine nucleotides and adenosine metabolism in pig kidney proximal tubule membranes

Exogenous adenosine triphosphate (ATP) added to brush-border membrane vesicles was rapidly degraded mainly to inosine according to the high ecto-nucleotidase activities in these vesicles. In the absence of phosphate, inosine was slowly transformed into hypoxanthine, and xanthine oxidase and dehydrogenase activities were not detected. The presence of ecto-adenosine deaminase and ecto-adenosine monophosphate (AMP) nucleotidase was shown. The ecto-adenosine deaminase was inhibited by deoxycoformycin and was also detected in rat renal brush-border membrane vesicles. Using orthovanadate, levamisole, and α, β-methylene adenosine diphosphate as possible inhibitors, alkaline phosphatase was shown to be the main agent responsible for ecto-AMP nucleotidase activity. In pig renal basolateral membrane vesicles and in whole cell extracts from pig renal cortex, ecto-AMP nucleotidase was the limiting factor in ATP degradation. Comparing the ATP catabolism in the whole cell cortical extract with the catabolism in the same sample precleared of membranes, it was shown that ectonucleotidase activity is mainly bound to the membranous components. It is also shown that the whole cell extract of pig renal cortex has hypoxanthine phosphoribosyl transferase activity, and it seems probable that the rapid and specific formation of luminal inosine and its transport into the cell in competition with adenosine may start the purine salvage pathway through the synthesis of IMP from hypoxanthine. © Wiley-Liss, Inc.     

Metabolism of Exogenous Purine Bases and Nucleosides by Salmonella typhimurium

Purine-requiring mutants of Salmonella typhimurium LT2 containing additional mutations in either adenosine deaminase or purine nucleoside phosphorylase have been constructed. From studies of the ability of these mutants to utilize different purine compounds as the sole source of purines, the following conclusions may be drawn. (i) S. typhimurium does not contain physiologically significant amounts of adenine deaminase and adenosine kinase activities. (ii) The presence of inosine and guanosine kinase activities in vivo was established, although the former activity appears to be of minor significance for inosine metabolism. (iii) The utilization of exogenous purine deoxyribonucleosides is entirely dependent on a functional purine nucleoside phosphorylase. (iv) The pathway by which exogenous adenine is converted to guanine nucleotides in the presence of histidine requires a functional purine nucleoside phosphorylase. Evidence is presented that this pathway involves the conversion of adenine to adenosine, followed by deamination to inosine and subsequent phosphorolysis to hypoxanthine. Hypoxanthine is then converted to inosine monophosphate by inosine monophosphate pyrophosphorylase. The rate-limiting step in this pathway is the synthesis of adenosine from adenine due to lack of endogenous ribose-l-phosphate.     

Purine metabolism in Acholeplasma laidlawii B: novel PPi-dependent nucleoside kinase activity

Acholeplasma laidlawii B-PG9 was examined for 16 cytoplasmic enzymes with activity for purine salvage and interconversion. Phosphoribosyltransferase activities for adenine, guanine, xanthine, and hypoxanthine were shown. Adenine, guanine, xanthine, and hypoxanthine were ribosylated to their nucleoside. Adenosine, inosine, xanthosine, and guanosine were converted to their base. No ATP-dependent phosphorylation of nucleosides to mononucleotides was found. However, PPi-dependent phosphorylation of adenosine, inosine, and guanosine to AMP, inosine monophosphate, and GMP, respectively, was detected. Nucleotidase activity for AMP, inosine monophosphate, xanthosine monophosphate, and GMP was also found. Interconversion of GMP to AMP was detected. Enzyme activities for the interconversion of AMP to GMP were not detected. Therefore, A. laidlawii B-PG9 cannot synthesize guanylates from adenylates or inosinates. De novo synthesis of purines was not detected. This study demonstrates that A. laidlawii B-PG9 has the enzyme activities for the salvage and limited interconversion of purines and, except for purine nucleoside kinase activity, is similar to Mycoplasma mycoides subsp. mycoides. This is the first report of a PPi-dependent nucleoside kinase activity in any organism.     

Changes in the activity of enzymes involved in purine "salvage" and nucleic acid degradation during the growth of Catharanthus roseus cells in suspension culture

Changes during growth in the activity of several enzymes involved in purine "salvage", adenine phosphoribosyltransferase (EC 2.4.2.7), guanine phosphoribosyl-transferase (EC 2.4.2.8), hypoxanthine phosphoribosyltransferase (EC 2.4.2.8) and adenosine kinase (EC 2.7.1.20), the enzymes which catalyze the conversion of nucleoside monophosphate to triphosphate, nucleoside monophosphate kinase (EC 2.7.4.4) and nucleoside diphosphate kinase (EC 2.7.4.6), and several degradation enzymes, deoxyribonucleae(s), ribonuclease(s). phosphatase(s), nucleosidase (EC 3.2.2.1), 3'-nucleotidase (EC 3.1.3.6) and 5'-nucleotidase (EC 3.1.3.5) were examined in cells of Catharanthus roseus (L.) G. Don cultured in suspension. In addition, the incorporation of [8-¹⁴C] adenine, [8-¹⁴C] adenine, [8-¹⁴C]hypoxanthine. [8-¹⁴C] adenosine and [8-¹⁴C]inosine into nucleotides and nucleic acids was also determined using intact cells.
The activities of all purine "salvage" enzymes examined and those of nucleoside monophosphate and diphosphate kinases increased rapidly during the lag phase and decreased during the following cell division and cell expansion phases. The rate of incorporation of adenine, guanine, hypoxanthine, and adenosine into nucleotides and nucleic acids was higher in the lag phase cells than during the following three phases. The highest rate of [8-¹⁴C]inosine incorporation was observed in the stationary phase cells. The activity of all degradation enzymes examined decreased when the stationary phase cells were transferred to a new medium.
These results indicated that the increased activity of purine "salvage" enzymes observed in the lag phase cells may contribute to an active purine "salvage" which is required to initiate a subsequent cell division.     

Ecto-5'-nucleotidase can provide the total purine requirements of mitogen-stimulated human T cells and rapidly dividing human B lymphoblastoid cells

The ability of mitogen-stimulated human T cells or rapidly dividing human B lymphoblastoid cells to drive their total purine requirements from inosine 5'-monophosphate, inosine, or hypoxanthine was compared. Inosine 5'-monophosphate first must be converted to inosine by the action of the enzyme ecto-5'-nucleotidase before it can be transported into the cell; inosine and hypoxanthine, however, can be transported directly. Mitogen-stimulated human peripheral blood T cells were treated with aminopterin to inhibit purine synthesis de novo and to make the cells dependent on an exogenous purine source. Thymidine was added as a source of pyrimidines. Under these conditions, 30 microM inosine 5'-monophosphate, inosine, and hypoxanthine showed comparable abilities to support [3H]thymidine incorporation into DNA or [3H]leucine incorporation into protein at rates equal to that of untreated control cultures. Similar results were found when azaserine was used to inhibit purine synthesis de novo, and thus DNA synthesis. In parallel experiments with the rapidly dividing human B lymphoblastoid cell line WI-L2, treatment with aminopterin (plus thymidine) inhibited the growth rate by greater than 95%. The normal growth rate was restored by the addition of 30 microM inosine 5'-monophosphate, inosine, or hypoxanthine to the medium. However, in similar experiments with cell line 1254, a derivative of WI-L2 which lacks detectable ecto-5'-nucleotidase activity, inosine and hypoxanthine (plus thymidine), but not inosine 5'-monophosphate (and thymidine) were able to restore the growth inhibition due to aminopterin. These results show that the catalytic activity of ecto-5'-nucleotidase is sufficient to meet the total purine requirements of mitogen-stimulated human T cells or rapidly dividing human B lymphoblastoid cells, and suggest that this enzyme may be important for purine salvage when rates of purine synthesis de novo are limited and/or an extracellular source of purine nucleotides is available.     

Differences between rat liver epithelial cells and fibroblast cells in sensitivity to 8-azaguanine

Summary Epithelial and fibroblast cells from adult rat liver were found to differ markedly in their sensitivities to the toxic effects of the purine analog, 8-azaguanine. Epithelial cells were rapidly killed by 8-azaguanine, whereas fibroblast cells suffered no observable toxicity. The resistance of fibroblast cells was not due to impermeability since it was shown by autoradiography that both cell types took up and utilized exogenous purines. Moreover, both cell types were sensitive to 6-thioguanine. The fibroblast cells, however, possessed a greater guanase activity than did the epithelial cells, measured by conversion of 8-azaguanine to 8-azaxanthine in the cell lines. Both cell types possessed hypoxanthine-guanine phosphoribosyl transferase for phosphoribosylating exogenous purines and thus making them metabolically available. Epithelial cell lysates convert 8-azaguanine to 8-azaguanosine-5′-monophosphate, the toxic metabolite of 8-azaguanine. Fibroblast cell lysates converted much more 8-azaguanine to 8-azaguanosine, an inactive metabolite, than did the epithelial cells. This conversion was presumably due to the much greater activity of 5′-nucleotidase in fibroblasts than epithelial cells; it degrades 8-azaguanosine-5′-monophosphate to 8-azaguanosine. These differences in purine metabolism suggest that fibroblast resistance to 8-azaguanine is due to the combination of a significant guanase activity that limits the amount of 8-azaguanine available and a high 5′-nucleotidase activity that would result in conversion of 8-azaguanosine-5-monophosphate, the toxic metabolite of 8-azaguanine, to 8-azaguanosine. This work was supported by Grant ES-01-724-01 from the National Institute of Environmental Health Sciences. C. T. is a recipient of the Young Environmental Scientist Health Research Grant Program, NIEHS.     

Metabolism of 6-Mercaptopurine by Resistant Escherichia coli Cells

Coggin, Joseph H. (University of Chicago, Chicago, Ill.), Muriel Loosemore, and William R. Martin. Metabolism of 6-mercaptopurine by resistant Escherichia coli cells. J. Bacteriol. 92:446-454. 1966.-6-Mercaptopurine (MP) utilization as a source of purine in MP-sensitive and -resistant cultures of Escherichia coli was investigated. The label of MP-8-C(14) appeared in adenine and guanine of ribonucleic acid and deoxyribonucleic acid in sensitive and resistant cultures. Studies using MP-S(35) further demonstrated that the MP moiety was degraded, as shown by a rapid decrease in radioactivity from cells upon exposure to MP for 20 min. Enzymatic analysis showed that MP was converted to 6-mercaptopurine ribonucleotide (MPRP) by extracts derived from both sensitive and resistant cells. Resistant cell preparations, however, degraded MPRP to inosine monophosphate (IMP) rapidly when compared with analogue degradation by sensitive cells. Inosineguanosine-5'-phosphate pyrophosphorylase from resistant cells did not catalyze the synthesis of IMP from hypoxanthine when the cells were cultured in the presence of MP, but these enzyme preparations actively converted guanine to guanosine monophosphate (GMP). Pyrophosphorylase derived from resistant cells cultured in medium without MP catalyzed the conversion of hypoxanthine to IMP and also guanine to GMP. These observations suggest that inosine-guanosine-5'-phosphate pyrophosphorylase is composed of two distinct enzymes. The mode of resistance to MP in E. coli is related to an enhancement of the enzymatic degradation of MPRP to the pivotal purine intermediate, IMP.     

Enzymatic Synthesis of 5-Methyluridine from Adenosine and Thymine with High Efficiency

5-Methyluridine (5MU) was synthesized efficiently from adenosine, thymine, and phosphate by a combination of adenosine deaminase (ADA), purine nucleoside phosphorylase (PUNP), pyrimidine nucleoside phosphorylase (PYNP), and xanthine oxidase (XOD). Adenosine was converted into inosine first by ADA. 5MU and hypoxanthine were synthesized from inosine and thymine by PUNP and PYNP. The hypoxanthine formed was converted into urate via xanthine by XOD. After inosine was completely consumed, an equilibrium state, in which 5MU, thymine, ribose-1-phosphate, and phosphate were involved, was achieved. At the equilibrium state, the maximum yield of 5MU was obtained. The yield of 5MU was 74%, when the initial concentrations of adenosine, thymine, and phosphate were 5 mM each. On the other hand, in the absence of ADA or XOD the yield of 5MU was 1.8%. Several kinds of nucleosides were also synthesized with high yield by the same method.     

Stimulation of phosphoribosyl pyrophosphate and purine nucleotide production by pyrroline 5-carboxylate in human erythrocytes

Recent studies have shown that pyrroline 5-carboxylate, the intermediate in the interconversions of proline, ornithine, and glutamate, can regulate the metabolism of erythrocytes. We now report that the formation of 5-phosphoribosyl 1-pyrophosphate (PP-Rib-P) was markedly stimulated by pyrroline 5-carboxylate in intact red cells. The production of PP-Rib-P is an important point of regulation in nucleotide metabolism. We found that pyrroline 5-carboxylate increased glucose metabolism through the oxidative arm of the pentose shunt, ribose 5-phosphate formation, and PP-Rib-P production and subsequently augmented purine nucleotide production through the salvage pathway in erythrocytes. We now report that pyrroline 5-carboxylate markedly stimulated the net synthesis of inosine monophosphate from hypoxanthine in intact human red cells so that the pool of inosine monophosphate became 20-30% of the total pool of purine nucleotides. Inosine monophosphate has been considered to be a "mobile pool" of purines, i.e. a reservoir from which peripheral tissues can be supplied; the effect of pyrroline 5-carboxylate on the inosine monophosphate pool may be a mechanism for regulating the function of erythrocytes in purine delivery.     

Hematopoiesis and the inosine modification in transfer RNA

Human promyelocytic leukemia (HL-60) cells were used to begin to evaluate the role in hematopoiesis of inosine biosynthesis in the tRNA anticodon wobble position; a reaction involving the enzymatic insertion of performed hypoxanthine. Dimethyl sulfoxide (DMSO) and hypoxanthine were found to induce the differentiation of HL-60 cells in a synergistic manner, and the induced differentiation was independent of changes in the purine catabolic enzymes adenosine deaminase and purine nucleoside phosphorylase. The short-term exposure of HL-60 cells to DMSO plus hypoxanthine resulted in enhanced leucine incorporation, and a model is presented showing how the inosine modification reaction in tRNA may be involved. A means by which hypoxanthine insertion into tRNA may modulate the synthesis of regulatory proteins (e.g., lymphokines and cell surface receptors) is also outlined.     

Assay of hypoxanthine-guanine phosphoribosyltransferase in human fibroblast lysates: inactivation of nucleotidase.

Assays of the hypoxanthine-guanine phosphoribosyltransferase enzyme (HGPRT: EC 2.4.2.8) in human fibroblast lysates are affected by the presence of a nucleotidase enzyme which converts the reaction product nucleotide to nucleoside. These enzymes, HGPRT and nucleotidase, have substantially different thermostabilities and pH optima, and the nucleotidase activity can be selectively eliminated. The conditions include preheating the cell lysates at 60°C for 10 min, a temperature at which the HGPRT enzyme is relatively stable, and using HGPRT assays buffered at pH 10. Also, we provide evidence that there is no nucleotidase activity in human lymphoblast lysates. Thus, human lymphoblast and preheated fibroblast lysates can be assayed for HGPRT activity by the DEAE-filter disk method.     

Genetic studies on the role of the nucleoside transport function in nucleoside efflux, the inosine cycle, and purine biosynthesis.

A mutant clone (AU-100) which is 90% deficient in adenylosuccinate synthetase activity was characterized from wild-type murine S49 T-lymphoma cells. This AU-100 cell line and its hypoxanthine-guanine phosphoribosyltransferase-deficient derivative, AUTG-50B, overproduce purines severalfold and excrete massive amounts of inosine into the culture medium (Ullman et al., Proc. Natl. Acad. Sci. U.S.A. 79:5127-5131, 1982). We introduced a mutation into both of these cell lines which make them incapable of taking up nucleosides from the culture medium. The genetic deficiency in nucleoside transport prevents the adenylosuccinate synthetase-deficient AU-100 cells from excreting inosine. Because of an extremely efficient intracellular inosine salvage system, the nucleoside transport-deficient AU-100 cells also no longer overproduce purines. AUTG-50B cells which have been made genetically deficient in nucleoside transport still overproduce purines but excrete hypoxanthine rather than inosine. These studies demonstrate genetically that nucleoside transport and nucleoside efflux share a common component and that nucleoside transport has an important regulatory function which profoundly affects the rates of purine biosynthesis and purine salvage.     

Metabolism of purines in cultured normal and HPRT-deficient human fibroblasts

Very low erythrocyte hypoxanthine phosphoribosyl transferase activity was found in a 6-month-old child with microcephaly, hyperuricemia, and retardation of central nervous development, who subsequently developed self-mutilation. Fibroblast cell extracts from this patient showed less than 6% of normal activity of HPRT. Major metabolic products of adenine-8-C¹⁴ by extracts from both the patient and normal subjects were identified by high-voltage electrophoresis and paper chromatography as adenosine 5-monophosphate, adenosine, and inosine. Inosine was the principal product of the fibroblast cell extracts from the first biopsy of the patient, whereas the normal fibroblast cell extracts produced predominantly adenosine. These results suggest that interconversion of the purine nucleotides plays a significant role in metabolism of these fibroblast cell extracts.This project received support from the M.R.C. grant MA-3331 and the Canadian Arthritis and Rheumatism Society.     

Purine accumulation in human fat cell suspensions. Evidence that human adipocytes release inosine and hypoxanthine rather than adenosine

Human adipocytes are of limited viability (7 +/- 2% release of lactate dehydrogenase/h) and contain active ectophosphatases which are capable of sequentially degrading ATP to adenosine. At densities of 30,000-40,000 cells/ml, human fat cell suspensions accumulated adenosine, inosine, and hypoxanthine, and their concentrations were 38 +/- 8, 120 +/- 10, and 31 +/- 7 nmol/liter after 3 h of incubation. Dipyridamole (10 mumol/liter), an inhibitor of nucleoside transport, caused a 5-7-fold increase in adenosine accumulation which was reduced by 85% on inhibition of ectophosphatases by beta-glycerophosphate and antibodies against ecto-5'-nucleotidase or alpha, beta-methylene 5'-adenosine diphosphate (10 mumol/liter), respectively, indicating that most of the adenosine is produced in the extracellular compartment. Accordingly, the spontaneous accumulation of adenosine was reduced beyond 5 nmol/liter on inhibition of ectophosphatase activities or removal of extracellular AMP by AMP deaminase (4 units/ml). Added adenosine (30 nmol/liter) disappeared until its concentration approached 5 nmol/liter. Isoproterenol (1 mumol/liter) had no effect on adenosine accumulation regardless whether purine production from extracellular sources was minimized or not. In contrast to adenosine, the concentrations of inosine and hypoxanthine displayed only a modest decrease (30-50%) on inhibition of ectophosphatase activities. In addition, isoproterenol caused a 2-3-fold increase in inosine and hypoxanthine production which was concentration-dependent and could be inhibited by propranolol. It is concluded that the adenosine that accumulates in human adipocyte suspensions is almost exclusively derived from adenine nucleotides which are released by leaking cells. By contrast, inosine and hypoxanthine are produced inside the cells, and the release of these latter purines appears to be linked to ATP turnover via adenylate cyclase.     

Inosine 5'-monophosphate vs inosine and hypoxanthine as substrates for purine salvage in human lymphoid cells

The ability of inosine 5'-monophosphate vs inosine or hypoxanthine to supply the total purine requirements of mitogen-stimulated human T cells or rapidly dividing human B lymphoblastoid cells was evaluated. Mitogen-stimulated human peripheral blood T cells were treated with aminopterin to inhibit purine synthesis de novo and make the cells dependent upon an exogenous purine source. Thymidine was added as a source of pyrimidines. Under these conditions, 25 microM inosine 5'-monophosphate, inosine, and hypoxanthine showed comparable abilities to support [3H]thymidine incorporation into DNA at rates equal to that of untreated control cultures. In parallel experiments with the rapidly dividing human B lymphoblastoid cell line, WI-L2, treatment with aminopterin (plus thymidine) inhibited the growth rate by greater than 95%. The normal growth rate was restored by the addition of 30 microM inosine 5'-monophosphate, inosine, or hypoxanthine to the medium. However, in similar experiments with cell line No. 1254, a derivative of WI-L2 which lacks detectable ecto-5'-nucleotidase activity, only inosine and hypoxanthine (plus thymidine), but not inosine 5'-monophosphate (and thymidine) were able to restore the growth inhibition due to aminopterin. These results show that the catalytic activity of ecto-5'-nucleotidase is sufficient to meet the total purine requirements of mitogen-stimulated human T cells or rapidly dividing human B lymphoblastoid cells and suggest that this enzyme may have functional significance when rates of purine synthesis de novo are limited and/or an extracellular source of purine nucleotides is available.     

Deoxyguanosine toxicity on lymphoid cells as a cause for immunosuppression in purine nucleoside phosphorylase deficiency.

To delineate the pathogenesis of the immunodeficiency disease associated with purine nucleoside phosphorylase deficiency, the effects of guanosine, inosine, deoxyguanosine and deoxyinosine on the growth of a mouse T cell lymphoma line in culture were studied. Of these four purine nucleosides, deoxyguanosine was the most toxic. At 5 x 10^?6 to 10^?5 M, deoxyguanosine inhibits growth of the lymphoma cells; higher concentrations result in complete killing. The cytotoxic effects of this deoxynucleoside can be prevented by simultaneous addition to culture medium of deoxycytidine and hypoxanthine. Determination of nucleotide pools in deoxyguanosine-treated cells shows a marked reduction of the deoxycytidine triphosphate and the adenine ribonucleotide pools, accompanied by a sharp rise in the guanosine deoxyribonucleotide and a smaller increase in the corresponding ribonucleotide pools.Deoxyguanosine as well as guanosine, inosine and deoxyinosine were known to accumulate to relatively high levels in the plasma of a patient with T cell immunodeficiency disease associated with purine nucleoside phosphorylase deficiency. The other three purine nucleosides are much less toxic than deoxyguanosine. Thus it is very probable that the patient's clinical manifestations of T lymphocytopenia are the consequence of deoxyguanosine inhibition of lymphoid cell proliferation, resulting from depletion of deoxycytidine triphosphate and adenine nucleotides.     

Metabolic fate of extracellular NAD in human skin fibroblasts

Extracellular NAD is degraded to pyridine and purine metabolites by different types of surface-located enzymes which are expressed differently on the plasmamembrane of various human cells and tissues. In a previous report, we demonstrated that NAD-glycohydrolase, nucleotide pyrophosphatase and 5'-nucleotidase are located on the outer surface of human skin fibroblasts. Nucleotide pyrophosphatase cleaves NAD to nicotinamide mononucleotide and AMP, and 5'-nucleotidase hydrolyses AMP to adenosine. Cells incubated with NAD, produce nicotinamide, nicotinamide mononucleotide, hypoxanthine and adenine. The absence of ADPribose and adenosine in the extracellular compartment could be due to further catabolism and/or uptake of these products. To clarify the fate of the purine moiety of exogenous NAD, we investigated uptake of the products of NAD hydrolysis using U-[(14)C]-adenine-NAD. ATP was found to be the main labeled intracellular product of exogenous NAD catabolism; ADP, AMP, inosine and adenosine were also detected but in small quantities. Addition of ADPribose or adenosine to the incubation medium decreased uptake of radioactive purine, which, on the contrary, was unaffected by addition of inosine. ADPribose strongly inhibited the activity of ecto-NAD-hydrolyzing enzymes, whereas adenosine did not. Radioactive uptake by purine drastically dropped in fibroblasts incubated with (14)C-NAD and dipyridamole, an inhibitor of adenosine transport. Partial inhibition of [(14)C]-NAD uptake observed in fibroblasts depleted of ATP showed that the transport system requires ATP to some extent. All these findings suggest that adenosine is the purine form taken up by cells, and this hypothesis was confirmed incubating cultured fibroblasts with (14)C-adenosine and analyzing nucleoside uptake and intracellular metabolism under different experimental conditions. Fibroblasts incubated with [(14)C]-adenosine yield the same radioactive products as with [(14)C]-NAD; the absence of inhibition of [(14)C]-adenosine uptake by ADPribose in the presence of alpha-beta methyleneADP, an inhibitor of 5' nucleotidase, demonstrates that ADPribose coming from NAD via NAD-glycohydrolase is finally catabolised to adenosine. These results confirm that adenosine is the NAD hydrolysis product incorporated by cells and further metabolized to ATP, and that adenosine transport is partially ATP dependent.     

The effect of formycin B on mRNA translation and uptake of purine precursors in Leishmania mexicana

Formycin B is a structural analog of inosine that is a potent inhibitor of Leishmania multiplication. Formycin B is reportedly converted to formycin A nucleotides and incorporated into RNA by the organisms, and it is unclear whether the active form of the drug is the nucleoside itself or its several metabolites. We confirmed that formycin A nucleotides are formed by formycin B-exposed L. mexicana promastigotes, and determined that the intraparasite concentration of Formycin B and its metabolites was 6 times the extracellular formycin B concentration. Formycin B did not significantly inhibit purine nucleoside transport by intact promastigotes or purine base phosphoribosylation by parasite lysates. Thus, the nucleoside does not appear to inhibit these initial steps of purine nucleoside metabolism. Since RNA and protein synthesis in formycin B-treated intact promastigotes was found to be inhibited within 30 minutes, the effect of formycin A metabolites on leishmanial protein synthesis was investigated in in vitro protein synthesis experiments. Messenger RNA from formycin B-treated promastigotes was translated only 40% as efficiently as control promastigote mRNA by rabbit reticulocyte lysates. In addition, when formycin A-5'-triphosphate was preincubated with the rabbit reticulocyte lysates, translation of control mRNA was 86% inhibited. Formycin B toxicity to Leishmania promastigotes appears to be at least partially due to inhibition of protein synthesis by formycin A nucleotides and formycin A containing mRNA.