Purine Uptake and Utilization by the Avian Malaria Parasite Plasmodium lophurae*

SYNOPSIS. Plasmodium lophurae cannot carry out extensive de novo purine biosynthesis, and depends upon the host erythrocyte for a supply of preformed purines. Exogenous purines taken up by the parasitized erythrocyte may constitute a major source of preformed purines for parasite nucleotide biosynthesis. The uptake of exogenous radioactive purine compounds and their incorporation into nucleic acids by duck erythrocytes parasitized with P. lophurae, uninfected erythrocytes, and erythrocyte-free parasites were studied. P. lophurae was found to have a remarkable ability, both intracellularly and extracellularly, to take up and utilize certain exogenous purines such as adenosine, inosine, and hypoxanthine. Incorporation studies indicated that this species has a functional purine salvage pathway by which inosine, hypoxanthine, and adenosine can be converted to both adenine and guanine nucleotides.     

Purine and pyrimidine transport by cultured Novikoff cells. Specificities and mechanism of transport and relationship to phosphoribosylation.

Adenine, guanine, and hypoxanthine were rapidly incorporated into the acid-soluble nucleotide pool and nucleic acids by wild type Novikoff cells. Incorporation followed normal Michaelis-Menten kinetics, but the following evidence indicates that specific transport processes precede the phosphoribosyltransferase reactions and are the rate-limiting step in purine incorporation by whole cells. Cells of an azaguanine-resistant subline of Novikoff cells which lacked hypoxanthine-guanine phosphoribosyltransferase activity and failed to incorporate guanine or hypoxanthine into the nucleotide pool, exhibited uptake of guanine and hypoxanthine by a saturable process. Similarly, wild type cells which had been preincubated in a glucose-free basal medium containing KCN and iodoacetate transported guanine and hypoxanthine normally, although a conversion of these purines to nucleotides did not occur in these cells. The mutant and KCN-iodoacetate treated wild type cells also exhibited countertransport of guanine and hypoxanthine when preloaded with various purines, uracil, and pyrimidine nucleosides. The cells also possess a saturable transport system for uracil although they lack phosphoribosyltransferase activity for uracil. In the absence of phosphoribosylation, none of the substrates was accumulated against a concentration gradient. Thus transport is by facilitated diffusion (nonconcentrative transport). Furthermore, the apparent Km values for purine uptake by untreated wild type and azaguanine-resistant cells were higher and the apparent Vmax values were lower than those for the corresponding phosphoribosyltransferases...     

Purine metabolism in mesophyll protoplasts of tobacco (Nicotiana tabacum) leaves.

The overall metabolism of purines was studied in tobacco (Nicotiana tabacum) mesophyll protoplasts. Metabolic pathways were studied by measuring the conversion of radioactive adenine, adenosine, hypoxanthine and guanine into purine ribonucleotides, ribonucleosides, bases and nucleic acid constituents. Adenine was extensively deaminated to hypoxanthine, whereupon it was also converted into AMP and incorporated into nucleic acids. Adenosine was mainly hydrolysed to adenine. Inosinate formed from hypoxanthine was converted into AMP and GMP, which were then catabolized to adenine and guanosine respectively. Guanine was mainly deaminated to xanthine and also incorporated into nucleic acids via GTP. Increased RNA synthesis in the protoplasts resulted in enhanced incorporation of adenine and guanine, but not of hypoxanthine and adenosine, into the nucleic acid fraction. The overall pattern of purine-nucleotide metabolic pathways in protoplasts of tobacco leaf mesophyll is proposed.     

Toxoplasma gondii: Purine synthesis and salvage in mutant host cells and parasites

Toxoplasma gondii, growing exponentially in heavily infected mutant Chinese hamster ovary cells that had a defined defect in purine biosynthesis, did not incorporate [U-¹⁴C]glucose or [¹⁴C]formate into the guanine or adenine of nucleic acids. Intracellular parasites therefore must be incapable of synthesizing purines and depend on their host cells for them. Extracellular parasites, which are capable of limited DNA and RNA synthesis, efficiently incorporated adenosine nucleotides, adenosine, inosine, and hypoxanthine into their nucleic acids; adenosine 5′-monophosphate was the best utilized precursor. Extracellular parasites incubated with ATP labeled with ³H in the purine base and ³²P in the α-phosphate incorporated the purine ring 50-fold more efficiently than they did the α-phosphate. Thus, ATP is largely degraded to adenosine before it can be used by T. gondii for nucleic acid synthesis. Two pathways for the conversion of adenosine to nucleotides appear to exist, one involving adenosine kinase, the other hypoxanthine—guanine phosphoribosyl transferase. In adenosine kinase-less mutant parasites, the efficiency of incorporation of ATP or adenosine was reduced by 75%, which indicates the adenosine kinase pathway was predominant. Extracellular parasites incorporated ATP into both the adenine and the guanine of their nucleic acids, so ATP from the host cell could supply the entire purine requirement of T. gondii. However, ATP generated by oxidative phosphorylation in the host cell is not essential for parasites because they grew normally in a cell mutant that was deficient in aerobic respiration and almost completely dependent upon glycolysis.     

Studies on the Formation of Uricase by Streptomyces

The cells of a strain of Streptomyces sp. grown in a medium consisted of peptone, glucose and inorganic salts had little activity of urate degradation. The activity, however, was considerably promoted if the cells were incubated potassium phosphate buffer containing MgCl₂ and glucose, even in the absence of urate. Uricase activity of the cells was also significantly increased during the incubation without urate. The cells were shown to possess the activities of metabolizing adenine, guanine, hypoxanthine to urate. The incubation with these purines caused an acceleration of urate breakdown by the cells and a remarkable increase of uricase activity in the cells. However, the amounts of uricase produced differed considerably with the kind of purines added to the incubation mixture even in the same molar concentration, and was largest with hypoxanthine. The induced formation of uricase by the endogenously generated urate was discussed.     

α-Amylase Formation and Nucleic Acid Metabolism of Bacillus subtilis

The nucleic acid metabolism in washed cells of Bacillus subtilis was investigated with special reference to amylase formation of the bacterium. On incubation of the suspension of the washed cells, purines, pyrimidines and their related compounds were observed in the medium. However, in the medium of the cells incubated with a calcium chelater, where no amylase formation occurred, were detected adenosine- and guanosine-monophosphate in addition to those described above. The addition of a calcium chelater was also found to decrease the quantity of the nucleic acids being involved in the lysozyme-sensitive fraction of the bacterial cells, suggesting the possibility that the metabolism of nucleic acids in this fraction is closely related to amylase formation of the cells.     

Purine-less death in Plasmodium falciparum induced by immucillin-H, a transition state analogue of purine nucleoside phosphorylase.

Plasmodium falciparum is responsible for the majority of life-threatening cases of malaria. Plasmodia species cannot synthesize purines de novo, whereas mammalian cells obtain purines from de novo synthesis or by purine salvage. Hypoxanthine is proposed to be the major source of purines for P. falciparum growth. It is produced from inosine phosphorolysis by purine nucleoside phosphorylase (PNP). Immucillins are powerful transition state analogue inhibitors of mammalian PNP and also inhibit P. falciparum PNP as illustrated in the accompanying article (Kicska, G. A., Tyler, P. C., Evans, G. B., Furneaux, R. H., Kim, K., and Schramm, V. L. (2002) J. Biol. Chem. 277, 3219-3225). This work tests the hypothesis that erythrocyte and P. falciparum PNP are essential elements for growth and survival of the parasite in culture. Immucillin-H reduces the incorporation of inosine but not hypoxanthine into nucleic acids of P. falciparum and kills P. falciparum cultured in human erythrocytes with an IC(50) of 35 nm. Growth inhibition by Imm-H is reversed by the addition of hypoxanthine but not inosine, demonstrating the metabolic block at PNP. The concentration of Imm-H required for inhibition of parasite growth varies as a function of culture hematocrit, reflecting stoichiometric titration of human erythrocyte PNP by the inhibitor. Human and P. falciparum PNPs demonstrate different specificity for inhibition by immucillins, with the 2'-deoxy analogues showing marked preference for the human enzyme. The IC(50) values for immucillin analogue toxicity to P. falciparum cultures indicate that inhibition of PNP in both the erythrocytes and the parasite is necessary to induce a purine-less death.     

Nitrogen Metabolism in Paramecium aurelia

Nitrogen in cell fractions of Paramecium aurelia varied according to the growth medium. Trichloroacetic acid-soluble fractions of cells were chromatographer. Adenine, adenosine, guanine, guanosine, hypoxanthine, aspartic acid, glutamic acid, histidine, lysine, proline, and phenylalanine were identified. Fyrimidines and xanthine, or their respective ribosides and ribotides, were not detected. Ammonia was released into the medium by both actively growing and "resting" cells. Culture fluids of "resting"cells also contained hypoxanthine and lesser amounts of adenine and guanine. Urea, uric acid, creatine, cretonne, and ailantoin were absent.
Pyrimidine nitrogen seems excreted as dihydrouracil. The following enzymes were detected in homogenates and cell-free preparations: nucleotidases, nucleoside hydrolases, and cytidine deaminase. Urease, uricase, adenase, guanase, xanthine oxidase, adenosine deaminase, and 5'-adenylic acid deaminase were not present in this organism.
Purine and pyrimidine incorporation into nucleic acids was investigated by the use of radioactive tracers. Guanosine gives rise to nucleic-acid guanine and adenine; adenosine was precursor to nucleic acid adenine only. Formate was incorporated into purines; glycine was not. P. aurelia can interconvert cytidine and uridine; both give rise to nucleic acid thymine. The methyl group of thymine may be derived from formate.     

Purine metabolism by intracellular Chlamydia psittaci.

Purine metabolism was studied in the obligate intracellular bacterium Chlamydia psittaci AA Mp in the wild type and a variety of mutant host cell lines with well-defined deficiencies in purine metabolism. C. psittaci AA Mp cannot synthesize purines de novo, as assessed by its inability to incorporate exogenous glycine into nucleic acid purines. C. psittaci AA Mp can take ATP and GTP, but not dATP or dGTP, directly from the host cell. Exogenous hypoxanthine and inosine were not utilized by the parasite. In contrast, exogenous adenine, adenosine, and guanine were directly salvaged by C. psittaci AA Mp. Crude extract prepared from highly purified C. psittaci AA Mp reticulate bodies contained adenine and guanine but no hypoxanthine phosphoribosyltransferase activity. Adenosine kinase activity was detected, but guanosine kinase activity was not. There was no competition for incorporation into nucleic acid between adenine and guanine, and high-performance liquid chromatography profiles of radiolabelled nucleic acid nucleobases indicated that adenine, adenosine, and deoxyadenosine were incorporated only into adenine and that guanine, guanosine, and deoxyguanosine were incorporated only into guanine. Thus, there is no interconversion of nucleotides. Deoxyadenosine and deoxyguanosine were cleaved to adenine and guanine before being utilized, and purine (deoxy)nucleoside phosphorylase activity was present in reticulate body extract.     

Purines inhibit poly(ADP-ribose) polymerase activation and modulate oxidant-induced cell death.

Purines such as adenosine, inosine, and hypoxanthine are known to have potent antiinflammatory effects. These effects generally are believed to be mediated by cell surface adenosine receptors. Here we provide evidence that purines protect against oxidant-induced cell injury by inhibiting the activation of the nuclear enzyme poly(ADP-ribose) polymerase (PARP). Upon binding to broken DNA, PARP cleaves NAD+ into nicotinamide and ADP-ribose and polymerizes the latter on nuclear acceptor proteins such as histones and PARP itself. Overactivation of PARP depletes cellular NAD+ and ATP stores and causes necrotic cell death. We have identified some purines (hypoxanthine, inosine, and adenosine) as potential endogenous PARP inhibitors. We have found that purines (hypoxanthine > inosine > adenosine) dose-dependently inhibited PARP activation in peroxynitrite-treated macrophages and also inhibited the activity of the purified PARP enzyme. Consistently with their PARP inhibitory effects, the purines also protected interferon gamma + endotoxin (IFN/LPS) -stimulated RAW macrophages from the inhibition of mitochondrial respiration and inhibited nitrite production from IFN/LPS-stimulated macrophages. We have selected hypoxanthine as the most potent cytoprotective agent and PARP inhibitor among the three purine compounds, and investigated the mechanism of its cytoprotective effect. We have found that hypoxanthine protects thymocytes from death induced by the cytotoxic oxidant peroxynitrite. In line with the PARP inhibitory effect of purines, hypoxanthine has prevented necrotic cell death while increasing caspase activity and DNA fragmentation. As previously shown with other PARP inhibitors, hypoxanthine acted proximal to mitochondrial alterations as hypoxanthine inhibited the peroxynitrite-induced mitochondrial depolarization and secondary superoxide production. Our data imply that purines may serve as endogenous PARP inhibitors. We propose that, by affecting PARP activation, purines may modulate the pattern of cell death during shock, inflammation, and reperfusion injury.     

Distinction between Hypoxanthine and Xanthine Transport in Chlamydomonas reinhardtii

Chlamydomonas reinhardtii cells consumed hypoxanthine and xanthine by means of active systems which promoted purine intracellular accumulation against a high concentration gradient. Both uptake and accumulation were also observed in mutant strains lacking xanthine dehydrogenase activity. Xanthine and hypoxanthine uptake systems exhibited very similar Michaelis constants for transport and pH values, and both systems were induced by either hypoxanthine or xanthine. However, they differed greatly in the length of the lag phase before uptake induction, which was longer for hypoxanthine than for xanthine. Cells grown on ammonium and transferred to hypoxanthine media consumed xanthine before hypoxanthine, whereas cells transferred to xanthine media did not take up hypoxanthine until 2 hours after commencing xanthine consumption. Metabolic and photosynthetic inhibitors such as 2,4-dinitrophenol, 3-(3,4-dichlorophenyl)-1,1-dimethyl urea, and carbonylcyanide m-chlorophenylhydrazone inhibited to a different extent the hypoxanthine and xanthine uptake. Similarly, N-ethylmaleimide abolished xanthine uptake but slightly affected that of hypoxanthine. Hypoxanthine consumption was inhibited by adenine and guanine whereas that of xanthine was inhibited only by urate. We conclude that hypoxanthine and xanthine in C. reinhardtii are taken up by different active transport systems which work independently of the intracellular enzymatic oxidation of these purines.     

Purine excretion by mammalian cells deficient in adenosine kinase

An adenosine kinaseless (AK^?) mutant of the mouse fibroblast line 3T6 has been obtained in cell culture by evolution of resistance to 6-thio-methylpurine ribonucleoside and tubercidin. The mutant excretes purines (xanthine and hypoxanthine) into the culture medium. Human or mouse cells lacking hypoxanthine-guanine phosphoribosyl transferase (HPT^?) excrete increased amounts of purines, but a human cell mutant lacking both HPT and AK excretes considerably more hypoxanthine. The difference in hypoxanthine excretion between the HPT^? mutant and the HPT^? AK^? mutant originates from the adenosine normally reutilized through the activity of adenosine kinase. The activity of adenosine kinase is essential to retard the adenosine cycle and to prevent cellular loss of purines.     

Purine and pyrimidine contents of some desoxypentose nucleic acids

The distribution of purines and pyrimidines in desoxypentose nucleic acids prepared from a variety of animal and plant sources has been studied. 1. The nucleic acids were prepared from calf thymus, calf kidney, sheep spleen, horse spleen, chicken erythrocyte, turtle erythrocyte, trout sperm, shad testes, sea urchin sperm, wheat germ, and Pneumococcus Type III. 2. Separate hydrolyses were carried out for the determination of purines and pyrimidines. These procedures permitted nearly quantitative recovery of nucleic acid phosphorus in many of the preparations examined. 3. In the case of those preparations where a quantitative recovery was obtained it can be concluded that no bases other than adenine, guanine, thymine, and cytosine were present in appreciable amounts. 4. The distribution of purines and pyrimidines in all the nucleic acids studied renders the tetranucleotide hypothesis untenable. 5. The results of the analyses have indicated no great differences in the composition of these nucleic acids with respect to purines and pyrimidines.     

Origin of life: Consideration of alternatives to proteins and nucleic acids

Summary Starting with relatively simple, non-hydrolyzable compounds in aqueous solution, entirely spontaneous condensations give rise to polymers that contain purines, pyrimidines, amino acids, coenzymes, lipid components and even phosphate. The presence of certain lipid micelles allows significant product formation at millimolar substrate concentrations. The first step involves formation of a Michael adduct from--unsaturated carbonyl compounds and various nucleophiles. Polymerization of these adducts occurs via sequential Knoevenagel condensations. All reactions take place readily at temperatures below 45°. The polymers can act as macromolecular catalysts as evidenced by hydrolytic activity. The purines and pyrimidines in the polymers appear to be capable of both base pairing and stacking interactions with ribonucleic acids. Specific examples of potential alternatives to base pairing are presented. These results are discussed from the standpoint of the spontaneous development of reproducing molecules. Proteins and nucleic acids may be evolutionary developments which have displaced earlier biopolymers.     

Prokaryotes that grow optimally in acid have purine-poor codons in long open reading frames

In nucleic acids the N-glycosyl bonds between purines and their ribose sugar moities are broken under acid conditions. If one strand of a duplex DNA segment were more vulnerable to mutation than the other, then the archaeon Picrophilus torridus, with an optimum growth pH near zero, could have adapted by decreasing the purine content of that strand. Yet, P. torridus has an optimum growth temperature near 60°C, and thermophiles prefer purine-rich codons. We found that, as in other thermophiles, high growth temperature correlates with the use of purine-rich codons. The extra purines are often in third, non-amino acid determining, codon positions. However, as in other acidophiles, as open reading frame lengths increase, there is increased use of purine-poor codons, particularly those without purines in second, amino acid-determining, codon positions. Thus, P. torridus can be seen as adapting (a) to temperature by increasing its purines in all open reading frames without greatly impacting protein amino acid compositions, and (b) to pH by decreasing purines in longer open reading frames, thereby potentially impacting protein amino acid compositions. It is proposed that longer open reading frames, being larger mutational targets, have become less vulnerable to depurination by virtue of pyrimidine for purine substitutions.     

Facilitated transport of 6-mercaptopurine and 6-thioguanine and non-mediated permeation of 8-azaguanine in novikoff rat hepatoma cells and relationship to intracellular phosphoribosylation

6-Mercaptopurine and 6-thioguanine strongly inhibited the zero-trans entry of hypoxanthine into Novikoff rat hepatoma cells which lacked hypoxanthine/guanine phosphoribosyltransferase, whereas 8-azaguanine had no significant effect. 6-Mercaptopurine was transported by the hypoxanthine carrier with about the same efficiency as its natural substrates (Michaelis-Menten constant = 372 ± 23 μM; maximum velocity = 30 ± 0.7 pmol/μl cell H₂O per s). 8-Azaguanine entry into the cells, on the other hand, showed no sign of saturability and was not significantly affected by substrates of the hypoxanthine/guanine carrier. The rate of entry of 8-azaguanine at 10–100 μM amounted to only about 5% of that of hypoxanthine transport and was related to its lipid solubility in the same manner as observed for various substances whose permeation through the plasma membrane is believed to be non-mediated. Only the non-ionized form of 8-azaguanine (pK_a = 6.6) permeated the cell membrane.Studies with wild type Novikoff cells showed that permeation into the cell was the main rate-determining step in the conversion of extracellular 8-azaguanine to intracellular aza-GTP and its incorporation into nucleic acids. In contrast, 6-mercaptopurine was rapidly transported into cells and phosphoribosylated; the main rate-determining step in its incorporation into nucleic acids was the further conversion of 6-mercaptopurine riboside 5'-monophosphate.     

Identification of xanthine and hypoxanthine as components of assembly pheromone in excreta of argasid ticks

In addition to guanine, xanthine and hypoxanthine were identified in white spherules in excreta of five species ofArgas andOrnithodoros ticks by a reverse-phase high-performance liquid chromatography (HPLC) and a gas chromatographic method with mass spectrometric detection, (GC/MS). The mutual relationships of these purines in excreta ofArgas (Persicargas) persicus were found to be less than 1.5% for hypoxanthine, less than 9.0% for xanthine and 89.8–98.6%, for guanine. In excreta of other species, the relationships of purines were similar, with the exception ofArgas (A.) reflexus andA. (A.) polonicus, where the amount of hypoxanthine was rather elevated. Uric acid was also identified in some cases. The assembly efficacy of xanthine and hypoxanthine is similar to that of guanine, but xanthine significantly enhances the assembly efficacy of commercial guanine when mixed in ratio of about 125. Thus, xanthine seems to be the second important component of assembly pheromone of argasid ticks.     

The substrate specificity of purine phosphoribosyltransferases in Schizosaccharomyces pombe

1. The activities of the purine phosphoribosyltransferases (EC 2.4.2.7 and 2.4.2.8) in purine-analogue-resistant mutants of Schizosaccharomyces pombe were checked. An 8-azathioxanthine-resistant mutant lacked hypoxanthine phosphoribosyltransferase, xanthine phosphoribosyltransferase and guanine phosphoribosyltransferase activities (EC 2.4.2.8) and appeared to carry a single mutation. Two 2,6-diaminopurine-resistant mutants retained these activities but lacked adenine phosphoribosyltransferase activity (EC 2.4.2.7). This evidence, together with data on purification and heat-inactivation patterns of phosphoribosyltransferase activities towards the various purines, strongly suggests that there are two phosphoribosyltransferase enzymes for purine bases in Schiz. pombe, one active with adenine, the other with hypoxanthine, xanthine and guanine. 2. Neither growth-medium supplements of purines nor mutations on genes involved in the pathway for new biosynthesis of purine have any influence on the amount of hypoxanthine-xanthine-guanine phosphoribosyltransferase produced by this organism.