Rabbit erythrocyte purine nucleoside phosphorylase. Differential-inactivation studies.

1. Qualitative studies on the stability of rabbit erythrocyte purine nucleoside phosphorylase showed a marked decrease in the susceptibility of the enzyme to thermal inactivation and digestion by proteinases of different specificities in response to certain of its substrates. 2. The extent to which inosine stabilizes the enzyme against thermal and proteolytic inactivation is related in a quantitative manner to the concentration of this substrate; it is proposed that differences in the rates of inactivation of the enzyme may reflect substrate-induced conformational changes in the enzyme structure that could alter the binding properties of the enzyme in a kinetically significant way. 3. A synergistic effect in the stabilization of the enzyme is observed in response to both substrates, inosine and phosphate, when the enzyme is inactivated with Pronase. 4. In the presence of substrate an increased rate of inactivation after reaction with 5,5'-dithiobis-(2-nitrobenzoic acid) is reported. 5. Differential-inactivation studies were also carried out with calf spleen purine nucleoside phosphorylase, and the results are discussed in relation to the kinetic properties displayed by this enzyme.     

Characterization of the active site of homogeneous thyroid purine nucleoside phosphorylase.

Purine nucleoside phosphorylase (purine-nucleoside : orthophosphate ribosyltransferase, EC 2.4.2.1) has been purified approx. 4000-fold and to electrophoretic homogeneity from bovine thyroid glands. The isolated enzyme has a specific activity of 17 mumol . min-1 . mg-1. The native enzyme appears to have a molecular weight of 92 000 as determined by sedimentation equilibrum ultracentrifugation and is comprised of three subunits having a molecular weight of 31 000 each as shown by sodium dodecyl sulfate gel electrophoresis. The enzyme is irreversibly denatured below pH 5 and the enzyme-substrate complex is shown to have an ionization constant (pKa) of 9.2 which influences catalytic activity. The pH dependence of the kinetic constants identifies three amino acid ionizable protons. The binding of inosine is effected by an imidazole ring of histidine (pKa 5.65) and a sulfhydryl group of cysteine (pKa 8.5) and the maximal velocity is restricted by an epsilon-amino group which is essential for phosphate binding. The requirement of these residues for activity was confirmed by group-specific chemical modification. The presence of phosphate protected only the lysyl residue while inosine protected all three residues from chemical titration. A model is proposed for the catalytic mechanism of purine nucleoside phosphorylase.     

Uridine phosphorylase from Schistosoma mansoni

Uridine phosphorylase is the only pyrimidine nucleoside cleaving activity that can be detected in extracts of Schistosoma mansoni. The enzyme is distinct from the two purine nucleoside phosphorylases contained in this parasite. Although Urd is the preferred substrate, uridine phosphorylase can also catalyze the reversible phosphorolysis of dUrd and dThd, but not Cyd, dCyd, or orotidine. The enzyme was purified 170-fold to a specific activity of 2.76 nmol/min/mg of protein with a 16% yield. It has a Mr of 56,000 as determined by molecular sieving on Sephadex G-100. The mechanism of uridine phosphorylase is sequential. When Urd was the substrate, the KUrd = 13 microM and the KPi = 533 +/- 78 microM. When dThd was used as a substrate, the KdThd = 54 microM and the KPi = 762 +/- 297 microM. The Vmax with dThd was 53 +/- 9.8% that of Urd. dThd was a competitive inhibitor when Urd was used as a substrate. The enzyme showed substrate inhibition by Urd, dThd (greater than 0.125 mM) and phosphate (greater than 10 mM). 5-(Benzyloxybenzyloxybenzyl)acyclouridine was identified as a potent and specific inhibitor of parasite (Ki = 0.98 microM) but not host uridine phosphorylase. Structure-activity relationship studies suggest that uridine phosphorylase from S. mansoni has a hydrophobic pocket adjacent to the 5-position of the pyrimidine ring and indicate differences between the binding sites of the mammalian and parasite enzymes. These differences may be useful in designing specific inhibitors for schistosomal uridine phosphorylase which will interfere selectively with nucleic acids synthesis in this parasite.     

Purine nucleoside phosphorylase of rabbit liver. Mechanism of catalysis.

Initial velocity studies and product inhibition patterns for purine nucleoside phosphorylase from rabbit liver were examined in order to determine the predominant catalytic mechanism for the synthetic (forward) and phosphorolytic (reverse) reactions of the enzyme. Initial velocity studies in the absence of products gave intersecting or converging linear double reciprocal plots of the kinetic data for both the synthetic and phosphorolytic reactions of the enzyme. The observed kinetic pattern was consistent with a sequential mechanism, requiring that both substrates add to the enzyme before products may be released. The product inhibition patterns showed mutual competitive inhibition between guanine and guanosine as variable substrates and inhibitors. Ribose 1-phosphate and inorganic orthophosphate were also mutually competitive toward each other. Other combinations of substrates and products gave noncompetitive inhibition. Apparent inhibition constants calculated for guanine as competitive inhibitor and for ribose 1-phosphate as noncompetitive inhibitor of the enzyme, with guanosine as variable substrate, did not vary significantly with increasing concentrations of inorganic orthophosphate as fixed substrate. These results suggest that the mechanism was order and that substrates add to the enzyme in an obligatory order. Dead end inhibition studies carried out in the presence of the products guanine and ribose 1-phosphate, respectively, showed that the kinetically significant abortive ternary complexes of enzyme-guanine-inorganic orthophosphate (EQB) and enzyme-guanose-ribose 1-phosphate (EAP) are formed. The results of dead end inhibition studies are consistent with an obligatory order of substrate addition to the enzyme. The nucleoside or purine is probably the first substrate to form a binary complex with the enzyme, and with which inorganic orthophosphate or ribose 1-phosphate may interact as secondary substrates. The evidences presented in this investigation support an Ordered Theorell-Chance mechanism for the enzyme.     

Allosteric regulation of purine nucleoside phosphorylase.

Purine nucleoside phosphorylase (EC 2.4.2.1) from bovine spleen is allosterically regulated. With the substrate inosine the enzyme displayed complex kinetics: positive cooperativity vs inosine when this substrate was close to physiological concentrations, negative cooperativity at inosine concentrations greater than 60 microM, and substrate inhibition at inosine greater than 1 mM. No cooperativity was observed with the alternative substrate, guanosine. The activity of purine nucleoside phosphorylase toward the substrate inosine was sensitive to the presence of reducing thiols; oxidation caused a loss of cooperativity toward inosine, as well as a 10-fold decreased affinity for inosine. The enzyme also displayed negative cooperativity toward phosphate at physiological concentrations of Pi, but oxidation had no effect on either the affinity or cooperativity toward phosphate. The importance of reduced cysteines on the enzyme is thus specific for binding of the nucleoside substrate. The enzyme was modestly inhibited by the pyrimidine nucleotides CTP (Ki = 118 microM) and UTP (Ki = 164 microM), but showed greater sensitivity to 5-phosphoribosyl-1-pyrophosphate (Ki = 5.2 microM).     

Differential metabolism of guanine nucleosides by human lymphoid cell lines

Deficiency of the enzyme purine nucleoside phosphorylase is associated with a specific depletion of T cells which is presumably mediated by its substrate, 2'-deoxyguanosine. Inhibitors of this enzyme are therefore being developed as potential immunosuppressive agents. We have compared the effects of 8-aminoguanosine, a competitive inhibitor of purine nucleoside phosphorylase, on the metabolism of 2'-deoxyguanosine by human T lymphoblasts, B lymphoblasts, and mature T-cell lines. 8-Aminoguanosine markedly potentiates the accumulation of dGTP in T lymphoblasts, but results in increased GTP levels in B lymphoblasts and mature T cells. GTP accumulation is associated with ATP depletion of a magnitude similar to that seen with an inhibitor of de novo purine biosynthesis, but does not result in inhibition of either DNA or RNA synthesis. In contrast, direct inhibition of de novo purine biosynthesis sharply decreased the incorporation of [3H]uridine into both DNA and RNA. We conclude that the mechanism of cell damage resulting from prolonged accumulation of GTP appears to involve more than inhibition of de novo purine biosynthesis and consequent ATP depletion. Perturbations in guanine nucleotide pools resulting from partial inhibition of purine nucleoside phosphorylase activity in vivo could result in cellular toxicity not limited to the target T cell population.     

Phosphorolytic and ribosyl transfer mechanisms of purified chicken liver purine nucleoside phosphorylase

Purified chicken liver purine nucleoside phosphorylase shows two ionizable groups at the active site whose pKa were near pH 6.9 and 8; the molecular weight (67,000-89,000) depends on the protein concentration. Initial velocity studies and product inhibition patterns were consistent with a random mechanism, which is rapid equilibrium in the phosphorolytic reaction with a dead-end complex, but not in the synthetic reaction. Free inorganic orthophosphate purine nucleoside phosphorylase (Sephadex G-100) catalyzes a pentosyl transfer reaction from inosine to guanine according to a random Bi, Bi mechanism.     

Rabbit brain purine nucleoside phosphorylase. Physical and chemical properties. Inhibition studies with aminopterin, folic acid and structurally related compounds.

Rabbit brain purine nucleoside phosphorylase used in this study was purified 6000-fold to apparent homogeneity and a specific activity or 50 μmol min^?1 mg ^?1 protein. A molecular weight of 70.000 daltons was determined for the native enzyme by gel filtration on Sephadex. Electrophoresis on polyacrylamide gel, in presence of sodium dodecyl sulfate, gave a subunit molecular weight of 34,500 daltons, suggesting that the enzyme is dimeric with, probably, identical subunits. The relationship of the structure of certain biologically active substances to their inhibitory action on the enzyme was examined. Folic acid and the compound d,l-6-methyl 5,6,7,8-tetrahydropterine, with similar substituents on their primary ring structure, were competitive inhibitors of the enzyme. The inhibition constants calculated were 3.37 × 10^?5M for folic acid and 3.80 × 10^?5m for d,l-6-methyl 5,6,7,8-tetrahydropterine. Aminopterin and the purine analog 8-aza-2,6-diaminopurine, with similar substituents on their primary ring structure, were noncompetitive inhibitors of the enzyme. Their respective inhibition constants were 1.50 × 10^?4 and 1.95 × 10^?4m. Erythro-9-(2-hydroxy-3-nonyl) adenine, an adenosine deaminase inhibitor, was also examined for inhibitory potency with mammalian purine nucleoside phosphorylase, and was observed to be a competitive inhibitor of this enzyme, with an inhibition constant of 1.90 × 10^?4m. The Michaelis constant for the substrate guanosine was near 6.0 × 10^?5m. Physical probe of the nature of the functional groups which participate in enzymic catalysis implicated both histidine and cysteine as the essential catalytic species. Photooxidation studies suggested a pH-dependent sensitivity of an essential catalytic group, and its probable location at the active site.     

Hexamere purine nucleoside phosphorylase from Escherichia coli K-12. Kinetic analysis and mechanism of reaction

A kinetic analysis of the phosphorolytic reaction catalyzed by hexameric purine nucleoside phosphorylase II from E. coli K-12 in the presence and absence of reaction products was carried out. The results of the kinetic analysis are consistent with a rapid equilibrium random Bi-Bi mechanism, in which a dead-end ternary (enzyme.purine base.phosphate) complex is formed.     

Expression of human malaria parasite purine nucleoside phosphorylase in host enzyme-deficient erythrocyte culture. Enzyme characterization and identification of novel inhibitors

The intraerythrocytic human malaria parasite, Plasmodium falciparum, requires a source of hypoxanthine for nucleic acid synthesis and energy metabolism. Adenosine has been implicated as a major source for intraerythrocytic hypoxanthine production via deamination and phosphorolysis, utilizing adenosine deaminase and purine nucleoside phosphorylase, respectively. To study the expression and characteristics of human malaria purine nucleoside phosphorylase, P. falciparum was successfully cultured in purine nucleoside phosphorylase-deficient human erythrocytes to an 8% parasitemia level. Purine nucleoside phosphorylase activity was undetectable in the uninfected enzyme-deficient host red cells but after parasite infection rose to 1.5% of normal erythrocyte levels. The parasite purine nucleoside phosphorylase was not cross-reactive with antibody against human enzyme, exhibited a calculated native molecular weight of 147,000, and showed a single major electrophoretic form of pI 5.4 and substrate specificity for inosine, guanosine and deoxyguanosine but not xanthosine or adenosine. The Km values for substrates, inosine and guanosine, were 4-fold lower than that for the human erythrocyte enzyme. In these studies we have identified two novel potent inhibitors of both human erythrocyte and parasite purine nucleoside phosphorylase, 8-amino-5'-deoxy-5'-chloroguanosine and 8-amino-9-benzylguanine. These enzyme inhibitors may have some antimalarial potential by limiting hypoxanthine production in the parasite-infected erythrocyte.     

Interactions of calf spleen purine nucleoside phosphorylase with antiviral acyclic nucleoside phosphonate inhibitors: kinetics and emission studies.

Association between calf spleen purine nucleoside phosphorylase and a series of phosphonylalkoxyalkyl derivatives of purine bases was studied by inhibition kinetics and fluorimetric titrations. Dissociation constants, determined by fluorimetric titration in phosphate-free conditions, were lower than inhibition constants in 1 mM phosphate, and inhibition was still weaker in 50 mM phosphate, in accord with the postulated bisubstrate analogue character of this class of inhibitors.     

Methylthioinosine phosphorylase from Pseudomonas aeruginosa. Structure and annotation of a novel enzyme in quorum sensing

The PA3004 gene of Pseudomonas aeruginosa PAO1 was originally annotated as a 5'-methylthioadenosine phosphorylase (MTAP). However, the PA3004 encoded protein uses 5'-methylthioinosine (MTI) as a preferred substrate and represents the only known example of a specific MTI phosphorylase (MTIP). MTIP does not utilize 5'-methylthioadenosine (MTA). Inosine is a weak substrate with a k(cat)/K(m) value 290-fold less than MTI and is the second best substrate identified. The crystal structure of P. aeruginosa MTIP (PaMTIP) in complex with hypoxanthine was determined to 2.8 ? resolution and revealed a 3-fold symmetric homotrimer. The methylthioribose and phosphate binding regions of PaMTIP are similar to MTAPs, and the purine binding region is similar to that of purine nucleoside phosphorylases (PNPs). The catabolism of MTA in P. aeruginosa involves deamination to MTI and phosphorolysis to hypoxanthine (MTA → MTI → hypoxanthine). This pathway also exists in Plasmodium falciparum, where the purine nucleoside phosphorylase (PfPNP) acts on both inosine and MTI. Three tight-binding transition state analogue inhibitors of PaMTIP are identified with dissociation constants in the picomolar range. Inhibitor specificity suggests an early dissociative transition state for PaMTIP. Quorum sensing molecules are associated with MTA metabolism in bacterial pathogens suggesting PaMTIP as a potential therapeutic target.     

Phosphate inhibition of the conversion of ribose-1-phosphate--a product of purine nucleoside phosphorylase splitting in the phosphoribomutase reaction

Different phosphate concentrations were studied for their effect on the degradation of adenosine by rat liver homogenates. It is shown that phosphate considerably inhibits the phosphoribomutase reaction without a significant effect on adenosine deaminase and purine nucleoside phosphorylase activities, that leads to the ribose-1-phosphate accumulation and to the disturbance of nucleoside utilization in reactions of the pentose phosphate pathway. It is supposed that the inhibition of the phosphoribomutase reaction by phosphate is important for regulation of nucleoside and nucleotide formation in a cell.     

Ribose 1-phosphate and inosine activate uracil salvage in rat brain

The purpose of this study was to determine the mechanism by which inosine activates pyrimidine salvage in CNS. The levels of cerebral inosine, hypoxanthine, uridine, uracil, ribose 1-phosphate and inorganic phosphate were determined, to evaluate the Gibbs free energy changes (deltaG) of the reactions catalyzed by purine nucleoside phosphorylase and uridine phosphorylase, respectively. A deltaG value of 0.59 kcal/mol for the combined reaction inosine+uracil <==> uridine+hypoxanthine was obtained, suggesting that at least in anoxic brain the system may readily respond to metabolite fluctuations. If purine nucleoside phosphorolysis and uridine phosphorolysis are coupled to uridine phosphorylation, catalyzed by uridine kinase, whose activity is relatively high in brain, the three enzyme activities will constitute a pyrimidine salvage pathway in which ribose 1-phosphate plays a pivotal role. CTP, presumably the last product of the pathway, and, to a lesser extent, UTP, exert inhibition on rat brain uridine nucleotides salvage synthesis, most likely at the level of the kinase reaction. On the contrary ATP and GTP are specific phosphate donors.     

Role of salvage and phosphorylation in the immunostimulatory activity of C8-substituted guanine ribonucleosides

Lymphokine-like activity and selective stimulation of B cell growth is exerted by a group of synthetic ribonucleosides derivatized at C8 and exemplified by 8-bromoguanosine (8BrGuo), 8-mercaptoguanosine, and 7-methyl 8-oxoguanosine. However, relatively little is known about their molecular mechanism of action. Like naturally occurring nucleosides, 8BrGuo is taken up into lymphocytes by a process of facilitated diffusion. Naturally occurring nucleosides are then reclaimed by a well characterized salvage pathway, involving sequential phosphorolysis and phosphoribosylation. The studies reported in this communication demonstrate that, in contrast to naturally occurring nucleosides, 8BrGuo is not a substrate for salvage by purine nucleoside phosphorylase. The base that would be produced by putative phosphorolysis, 8-bromoguanine, is biologically inactive and is not a substrate for hypoxanthine-guanine phosphoribosyl-transferase. Accordingly, inhibitors of purine nucleoside phosphorylase-mediated salvage fail to inhibit nucleoside-induced immunostimulation selectively. Examination of the metabolism of 8BrGuo provides no direct evidence that 8BrGuo is phosphorylated by B lymphocytes. Direct enzymatic phosphorylation does not seem to be essential to the mechanism of action of the nucleoside insofar as competitive inhibition of deoxycytidine kinase (an enzyme that directly phosphorylates purines as well as pyrimidines) or of deoxyguanosine kinase fails to inhibit 8BrGuo stimulation selectively. Moreover, studies with synthetic nucleosides in which 3' and/or 5' hydroxyl groups were irreversibly blocked, precluding their phosphorylation, demonstrated that immunobiologic activity can occur in the absence of 3' and/or 5' phosphorylation. Finally, experiments with radiolabeled nucleosides provide no evidence to support the hypothesis that they are incorporated into cellular nucleic acid. These data, together with previous studies, suggest that it is the unmetabolized nucleoside that is active and, as such, is most likely to act in a regulatory capacity.     

The purine nucleoside phosphorylase from Trichomonas vaginalis is a homologue of the bacterial enzyme

Trichomonas vaginalis is a parasitic protozoan and the causative agent of trichomoniasis. Its primary purine salvage system, consisting of a purine nucleoside phosphorylase (PNP) and a purine nucleoside kinase, presents potential targets for designing selective inhibitors as antitrichomonial drugs because of lack of de novo synthesis of purine nucleotides in this organism. cDNA encoding T. vaginalis PNP was isolated by complementation of an Escherichia coli strain deficient in PNP and expressed, and the recombinant enzyme was purified to apparent homogeneity. It bears only 28% sequence identity with that of human PNP but 57% identity with the E. coli enzyme. Gel filtration showed the enzyme in a hexameric form, similar to the bacterial PNPs. Steady-state kinetic analysis of T. vaginalis PNP-catalyzed reactions gave K(m)'s of 31.5, 59.7, and 6.1 microM for inosine, guanosine, and adenosine in the nucleosidase reaction and 45.6, 35.9, and 12.3 microM for hypoxanthine, guanine, and adenine in the direction of nucleoside synthesis. This substrate specificity appears to be similar to that of bacterial PNPs. The catalytic efficiency of this enzyme with adenine as substrate is 58-fold higher than that with either hypoxanthine or guanine, representing a distinct disparity with the mammalian PNPs, which have negligible activity with either adenine or adenosine. The kinetic mechanism of T. vaginalis PNP-catalyzed reactions, determined by product inhibition and equilibrium isotope exchange, was by random binding of substrates (purine base and ribose 1-phosphate) with ordered release of the purine nucleoside first, followed by inorganic phosphate. Formycin A, an analogue of adenosine known as an inhibitor of E. coli PNP without any effect on mammalian PNPs, was shown to inhibit T. vaginalis PNP with a K(is) of 2.3 microM by competing with adenosine. T. vaginalis PNP thus belongs to the family of bacterial PNPs and constitutes a target for antitrichomonial chemotherapy.     

Transport of adenine, hypoxanthine and uracil into Escherichia coli.

Uptake of adenine, hypoxanthine and uracil by an uncA strain of Escherichia coli is inhibited by uncouplers or when phosphate in the medium is replaced by less than 1 mM-arsenate, indicating a need for both a protonmotive force and phosphorylated metabolites. The rate of uptake of adenine or hypoxanthine was not markedly affected by a genetic deficiency of purine nucleoside phosphorylase. In two mutants with undetected adenine phosphoribosyltransferase, the rate of adenine uptake was about 30% of that in their parent strain, and evidence was obtained to confirm that adenine had then been utilized via purine nucleoside phosphorylase. In a strain deficient in both enzymes adenine uptake was about 1% of that shown by wild-type strains. Uptake of hypoxanthine was similarly limited in a strain lacking purine nucleoside phosphorylase, hypoxanthine phosphoribosyltransferase and guanine phosphoribosyltransferase. Deficiency of uracil phosphoribosyltransferase severely limits uracil uptake, but the defect can be circumvented by addition of inosine, which presumably provides ribose 1-phosphate for reversal of uridine phosphorylase. The results indicate that there are porter systems for adenine, hypoxanthine and uracil dependent on a protonmotive force and facilitated by intracellular metabolism of the free bases.     

Pentose phosphates in nucleoside interconversion and catabolism

Ribose phosphates are either synthesized through the oxidative branch of the pentose phosphate pathway, or are supplied by nucleoside phosphorylases. The two main pentose phosphates, ribose-5-phosphate and ribose-1-phosphate, are readily interconverted by the action of phosphopentomutase. Ribose-5-phosphate is the direct precursor of 5-phosphoribosyl-1-pyrophosphate, for both de novo and 'salvage' synthesis of nucleotides. Phosphorolysis of deoxyribonucleosides is the main source of deoxyribose phosphates, which are interconvertible, through the action of phosphopentomutase. The pentose moiety of all nucleosides can serve as a carbon and energy source. During the past decade, extensive advances have been made in elucidating the pathways by which the pentose phosphates, arising from nucleoside phosphorolysis, are either recycled, without opening of their furanosidic ring, or catabolized as a carbon and energy source. We review herein the experimental knowledge on the molecular mechanisms by which (a) ribose-1-phosphate, produced by purine nucleoside phosphorylase acting catabolically, is either anabolized for pyrimidine salvage and 5-fluorouracil activation, with uridine phosphorylase acting anabolically, or recycled for nucleoside and base interconversion; (b) the nucleosides can be regarded, both in bacteria and in eukaryotic cells, as carriers of sugars, that are made available though the action of nucleoside phosphorylases. In bacteria, catabolism of nucleosides, when suitable carbon and energy sources are not available, is accomplished by a battery of nucleoside transporters and of inducible catabolic enzymes for purine and pyrimidine nucleosides and for pentose phosphates. In eukaryotic cells, the modulation of pentose phosphate production by nucleoside catabolism seems to be affected by developmental and physiological factors on enzyme levels.     

Unique substrate specificity of purine nucleoside phosphorylases from Thermus thermophilus

The degradation of purine nucleoside is the first step of purine nucleoside uptake. This degradation is catalyzed by purine nucleoside phosphorylase, which is categorized into two classes: hexameric purine nucleoside phosphorylase (6PNP) and trimeric purine nucleoside phosphorylase (3PNP). Generally, 6PNP and 3PNP degrade adenosine and guanosine, respectively. However, the substrate specificity of 6PNP and 3PNP of Thermus thermophilus (tt6PNP and tt3PNP, respectively) is the reverse of that anticipated based on comparison to other phosphorylases. Specifically, in this paper we reveal by gene disruption that tt6PNP and tt3PNP are discrete enzymes responsible for the degradation of guanosine and adenosine, respectively, in T. thermophilus HB8 cells. Sequence comparison combined with structural information suggested that Asn204 in tt6PNP and Ala196/Asp238 in tt3PNP are key residues for defining their substrate specificity. Replacement of Asn204 in tt6PNP with Asp changed the substrate specificity of tt6PNP to that of a general 6PNP. Similarly, substitution of Ala196 by Glu and Asp238 by Asn changed the substrate specificity of tt3PNP to that of a general 3PNP. Our results indicate that the residues at these positions determine substrate specificity of PNPs in general. Sequence analysis further suggested most 6PNP and 3PNP enzymes in thermophilic species belonging to the Deinococcus-Thermus phylum share the same critical residues as tt6PNP and tt3PNP, respectively.     

A second purine nucleoside phosphorylase in Escherichia coli K-12

Summary The presence of a second purine nucleoside phosphorylase in wild-type strains of E. coli K-12 after growth on xanthosine has been demonstrated. Like other purine nucleoside phosphorylases it is able to carry out both phosphorylosis and synthesis of purine deoxy- and ribonucleosides whilst pyrimidine nucleosides cannot act as substrates. In contrast to the well characterised purine nucleoside phosphorylase of E. coli K-12 (encoded by the deoD gene) this new enzyme could act on xanthosine and is hence called xanthosine phosphorylase. Studies of its substrate specificity showed that xanthosine phosphorylase, like the mammalian purine nucleoside phosphorylases, has no activity towards adenine and the corresponding nucleosides. Determinations of K _m and gel filtration behaviour was carried out on crude dialysed extracts. The presence of xanthosine phosphorylase enables E. coli to grow on xanthosine as carbon source. Xanthosine was the only compound found which induced xanthosine phosphorylase. No other known nucleoside catabolising enzyme was induced by xanthosine. The implications of non-linear induction kinetics of xanthosine phosphorylase is discussed.