Purine-nucleoside phosphorylase from Salmonella typhimurium and Escherichia coli. Initial velocity kinetics, ligand banding, and reaction mechanism

Synthesis of New 5′-Norcarbocyclic Aza/Deaza Purine Fleximers - Noncompetitive Inhibitors of E.coli Purine Nucleoside Phosphorylase

A new series of flexible 5′-norcarbocyclic aza/deaza-purine nucleoside analogs were synthesized from 6-oxybicyclo[3.1.0.]hex-2-ene and pyrazole-containing fleximer analogs of heterocyclic bases using the Trost procedure. The compounds were evaluated as potential inhibitors of E. coli purine nucleoside phosphorylase. Analog 1-3 were found to be noncompetitive inhibitors with inhibition constants of 14–24 mM. From the data obtained, it can be assumed that the new 5′-norcarbocyclic nucleoside analogs interact with the active site of the PNP like natural heterocyclic bases. But at the same time the presence of a cyclopentyl moiety with 2′ and 3′ hydroxyls is necessary for the inhibitory properties, since compounds 8–10, without those groups did not exhibit an inhibitory effect under the experimental conditions.

Single tryptophan Y160W mutant of homooligomeric E. coli purine nucleoside phosphorylase implies that dimers forming the hexamer are functionally not equivalent

E. coli purine nucleoside phosphorylase is a homohexamer, which structure, in the apo form, can be described as a trimer of dimers. Earlier studies suggested that ligand binding and kinetic properties are well described by two binding constants and two sets of kinetic constants. However, most of the crystal structures of this enzyme complexes with ligands do not hold the three-fold symmetry, but only two-fold symmetry, as one of the three dimers is different (both active sites in the open conformation) from the other two (one active site in the open and one in the closed conformation). Our recent detailed studies conducted over broad ligand concentration range suggest that protein–ligand complex formation in solution actually deviates from the two-binding-site model. To reveal the details of interactions present in the hexameric molecule we have engineered a single tryptophan Y160W mutant, responding with substantial intrinsic fluorescence change upon ligand binding. By observing various physical properties of the protein and its various complexes with substrate and substrate analogues we have shown that indeed three-binding-site model is necessary to properly describe binding of ligands by both the wild type enzyme and the Y160W mutant. Thus we have pointed out that a symmetrical dimer with both active sites in the open conformation is not forced to adopt this conformation by interactions in the crystal, but most probably the dimers forming the hexamer in solution are not equivalent as well. This, in turn, implies that an allosteric cooperation occurs not only within a dimer, but also among all three dimers forming a hexameric molecule.

Crystal structure of Escherichia coli purine nucleoside phosphorylase in complex with 7-deazahypoxanthine

Purine nucleoside phosphorylases (EC 2.4.2.1; PNPs) reversibly catalyze the phosphorolytic cleavage of glycosidic bonds in purine nucleosides to generate ribose 1-phosphate and a free purine base, and are key enzymes in the salvage pathway of purine biosynthesis. They also catalyze the transfer of pentosyl groups between purine bases (the transglycosylation reaction) and are widely used for the synthesis of biologically important analogues of natural nucleosides, including a number of anticancer and antiviral drugs. Potent inhibitors of PNPs are used in chemotherapeutic applications. The detailed study of the binding of purine bases and their derivatives in the active site of PNPs is of particular interest in order to understand the mechanism of enzyme action and for the development of new enzyme inhibitors. Here, it is shown that 7-deazahypoxanthine (7DHX) is a noncompetitive inhibitor of the phosphorolysis of inosine by recombinant Escherichia coli PNP (EcPNP) with an inhibition constant Ki of 0.13 mM. A crystal of EcPNP in complex with 7DHX was obtained in microgravity by the counter-diffusion technique and the three-dimensional structure of the EcPNP-7DHX complex was solved by molecular replacement at 2.51 Å resolution using an X-ray data set collected at the SPring-8 synchrotron-radiation facility, Japan. The crystals belonged to space group P6122, with unit-cell parameters a = b = 120.370, c = 238.971 Å, and contained three subunits of the hexameric enzyme molecule in the asymmetric unit. The 7DHX molecule was located with full occupancy in the active site of each of the three crystallographically independent enzyme subunits. The position of 7DHX overlapped with the positions occupied by purine bases in similar PNP complexes. However, the orientation of the 7DHX molecule differs from those of other bases: it is rotated by ∼180° relative to other bases. The peculiarities of the arrangement of 7DHX in the EcPNP active site are discussed.

Nucleotides, Nucleosides, and Nucleobases

We review literature on the metabolism of ribo- and deoxyribonucleotides, nucleosides, and nucleobases in Escherichia coli and Salmonella,including biosynthesis, degradation, interconversion, and transport. Emphasis is placed on enzymology and regulation of the pathways, at both the level of gene expression and the control of enzyme activity. The paper begins with an overview of the reactions that form and break the N-glycosyl bond, which binds the nucleobase to the ribosyl moiety in nucleotides and nucleosides, and the enzymes involved in the interconversion of the different phosphorylated states of the nucleotides. Next, the de novo pathways for purine and pyrimidine nucleotide biosynthesis are discussed in detail.Finally, the conversion of nucleosides and nucleobases to nucleotides, i.e.,the salvage reactions, are described. The formation of deoxyribonucleotides is discussed, with emphasis on ribonucleotidereductase and pathways involved in fomation of dUMP. At the end, we discuss transport systems for nucleosides and nucleobases and also pathways for breakdown of the nucleobases.

Homooligomerization is needed for stability: a molecular modelling and solution study of Escherichia coli purine nucleoside phosphorylase

Although many enzymes are homooligomers composed of tightly bound subunits, it is often the case that smaller assemblies of such subunits, or even individual monomers, seem to have all the structural features necessary to independently conduct catalysis. In this study, we investigated the reasons justifying the necessity for the hexameric form of Escherichia coli purine nucleoside phosphorylase - a homohexamer composed of three linked dimers - since it appears that the dimer is the smallest unit capable of catalyzing the reaction, according to the currently accepted mechanism. Molecular modelling was employed to probe mutations at the dimer-dimer interface that would result in a dimeric enzyme form. In this way, both in silico and in vitro, the hexamer was successfully transformed into dimers. However, modelling and solution studies show that, when isolated, dimers cannot maintain the appropriate three-dimensional structure, including the geometry of the active site and the position of the catalytically important amino acids. Analytical ultracentrifugation proves that E. coli purine nucleoside phosphorylase dimeric mutants tend to dissociate into monomers with dissociation constants of 20-80 μm. Consistently, the catalytic activity of these mutants is negligible, at least 6 orders of magnitude smaller than for the wild-type enzyme. We conclude that the hexameric architecture of E. coli purine nucleoside phosphorylase is necessary to provide stabilization of the proper three-dimensional structure of the dimeric assembly, and therefore this enzyme is the obligate (obligatory) hexamer.

STRUCTURED DIGITAL ABSTRACT

●PNP and PNP bind by molecular sieving (1, 2, 3, 4).

Crystal structure and molecular dynamics studies of purine nucleoside phosphorylase from Mycobacterium tuberculosis associated with acyclovir

Consumption has been a scourge of mankind since ancient times. This illness has charged a high price to human lives. Many efforts have been made to defeat Mycobacterium tuberculosis (Mt). The M. tuberculosis purine nucleoside phosphorylase (MtPNP) is considered an interesting target to pursuit new potential inhibitors, inasmuch it belongs to the purine salvage pathway and its activity might be involved in the mycobacterial latency process. Here we present the MtPNP crystallographic structure associated with acyclovir and phosphate (MtPNP:ACY:PO(4)) at 2.10 Å resolution. Molecular dynamics simulations were carried out in order to dissect MtPNP:ACY:PO(4) structural features, and the influence of the ligand in the binding pocket stability. Our results revealed that the ligand leads to active site lost of stability, in agreement with experimental results, which demonstrate a considerable inhibitory activity against MtPNP (K(i) = 150 nM). Furthermore, we observed that some residues which are important in the proper ligand's anchor into the human homologous enzyme do not present the same importance to MtPNP. Therewithal, these findings contribute to the search of new specific inhibitors for MtPNP, since peculiarities between the mycobacterial and human enzyme binding sites have been identified, making a structural-based drug design feasible.

Role of ionization of the phosphate cosubstrate on phosphorolysis by purine nucleoside phosphorylase (PNP) of bacterial (E. coli) and mammalian (human) origin

Kinetics of the reactions of purine nucleoside phosphorylases (PNP) from E. coli (PNP-I, the product of the deoD gene) and human erythrocytes with their natural substrates guanosine (Guo), inosine (Ino), a substrate analogue N(7)-methylguanosine (m(7)Guo), and orthophosphate (P(i), natural cosubstrate) and its thiophosphate analogue (SP(i)), found to be a weak cosubstrate, have been studied in the pH range 5-8. In this pH range Guo and Ino exist predominantly in the neutral forms (pK(a) 9.2 and 8.8); m(7)Guo consists of an equilibrium mixture of the cationic and zwitterionic forms (pK(a) 7.0); and P(i) and SP(i) exhibit equilibria between monoanionic and dianionic forms (pK(a) 6.7 and 5.4, respectively). The phosphorolysis of m(7)Guo (at saturated concentration) with both enzymes exhibits Michaelis kinetics with SP(i), independently of pH. With P(i), the human enzyme shows Michaelis kinetics only at pH approximately 5. However, in the pH range 5-8 for the bacterial enzyme, and 6-8 for the human enzyme, enzyme kinetics with P(i) are best described by a model with high- and low-affinity states of the enzymes, denoted as enzyme-substrate complexes with one or two active sites occupied by P(i), characterized by two sets of enzyme-substrate dissociation constants (apparent Michaelis constants, K (m1) and K (m2)) and apparent maximal velocities (V (max1) and V (max2)). Their values, obtained from non-linear least-squares fittings of the Adair equation, were typical for negative cooperativity of both substrate binding (K (m1) < K (m2)) and enzyme kinetics (V (max1)/K (m1) > V (max2)/K (m2)). Comparison of the pH-dependence of the substrate properties of P(i) versus SP(i) points to both monoanionic and dianionic forms of P(i) as substrates, with a marked preference for the dianionic species in the pH range 5-8, where the population of the P(i) dianion varies from 2 to 95%, reflected by enzyme efficiency three orders of magnitude higher at pH 8 than that at pH 5. This is accompanied by an increase in negative cooperativity, characterized by a decrease in the Hill coefficient from n (H) approximately 1 to n (H) approximately 0.7 for Guo with the human enzyme, and to n (H) approximately 0.7 and 0.5 for m(7)Guo with the E. coli and human enzymes, respectively. Possible mechanisms of cooperativity are proposed. Attention is drawn to the substrate properties of SP(i) in relation to its structure.

Identification of the tautomeric form of formycin A in its complex with Escherichia coli purine nucleoside phosphorylase based on the effect of enzyme-ligand binding on fluorescence and phosphorescence

Fluorescence and phosphorescence emission spectroscopy were employed to study the interaction of Escherichia coli purine nucleoside phosphorylase (PNP) with its specific inhibitor, formycin A (FA), a close structural analogue of adenosine (natural substrate), in the absence and presence of phosphate (P(i), substrate). Formation of enzyme-FA complexes led to marked quenching of enzyme tyrosine intrinsic fluorescence and phosphorescence, with concomitant increases in fluorescence and phosphorescence of FA. Fluorescence resonance energy transfer from the protein Tyr160 residue to the FA base moiety was identified as a major mechanism of protein fluorescence quenching, increased by addition of P(i). The effects of enzyme-FA interactions on the nucleoside excitation and emission spectra for fluorescence and phosphorescence revealed shifts in the tautomeric equilibrium of the bound FA, i.e. from the N(1)-H tautomer (predominant in solution) to the N(2)-H form, enhanced by the presence of P(i). The latter was confirmed by enzyme-ligand dissociation constant ( K(d)) values of 5.9+/-0.4 and 2.1+/-0.3 microM in the absence and presence of P(i), respectively. Addition of glycerol (80%, v/v) led to a lower enzyme affinity ( K(d) approximately 70 microM), without changes in binding stoichiometry. Enzyme-FA complex formation led to a higher increase of the fluorescence than the phosphorescence band of the ligand, consistent with the fact that the N(2)-H tautomer is characterized by a weaker phosphorescence than the N(1)-H tautomeric form. These results show, for the first time, the application of phosphorescence spectroscopy to the identification of the tautomeric form of the inhibitor bound by the enzyme.

Open and closed conformation of the E. coli purine nucleoside phosphorylase active center and implications for the catalytic mechanism

The crystal structure of the ternary complex of hexameric purine nucleoside phosphorylase (PNP) from Escherichia coli with formycin A derivatives and phosphate or sulphate ions is determined at 2.0 A resolution. The hexamer is found as a trimer of unsymmetric dimers, which are formed by pairs of monomers with active sites in different conformations. The conformational difference stems from a flexible helix (H8: 214-236), which is continuous in one conformer, and segmented in the other. With the continuous helix, the entry into the active site pocket is wide open, and the ligands are bound only loosely ("open" or "loose binding" conformation). By segmentation of the helix (H8: 214-219 and H8': 223-236, separated by a gamma-turn), the entry into the active site is partially closed, the pocket is narrowed and the ligands are bound much more tightly ("closed" or "tight binding" conformation). Furthermore, the side-chain of Arg217 is carried by the moving helix into the active site. This residue, conserved in all homologous PNPs, plays an important role in the proposed catalytic mechanism. In this mechanism, substrate binding takes place in the open, and and the catalytic action occurs in the closed conformation. Catalytic action involves protonation of the purine base at position N7 by the side-chain of Asp204, which is initially in the acid form. The proton transfer is triggered by the Arg217 side-chain which is moved by the conformation change into hydrogen bond distance to Asp204. The mechanism explains the broad specificity of E. coli PNP, which allows 6-amino as well as 6-oxo-nucleosides as substrates. The observation of two kinds of binding sites is fully in line with solution experiments which independently observe strong and weak binding sites for phosphate as well as for the nucleoside inhibitor.

Interaction of Escherichia coli purine nucleoside phosphorylase (PNP) with the cationic and zwitterionic forms of the fluorescent substrate N(7)-methylguanosine

Steady-state and time-resolved fluorescence spectroscopy, and enzyme kinetics, were applied to study the reaction of purine nucleoside phosphorylase (PNP) from Escherichia coli with its substrate N(7)-methylguanosine (m7Guo), which consists of an equilibrium mixture of cationic and zwitterionic forms (pK(a)=7.0), each with characteristic absorption and fluorescence spectra, over the pH range 6-9, where absorption and intrinsic fluorescence of the enzyme are virtually unchanged. The pH-dependence of kinetic constants for phosphorolysis of m7Guo were studied under condition where the population of the zwitterion varied from 10% to 100%. This demonstrated that, whereas the zwitterion is a 3- to 6-fold poorer substrate, if at all, than the cation for the mammalian enzymes, both ionic species are almost equally good substrates for E. coli PNP. The imidazole-ring-opened form of m7Guo is neither a substrate nor an inhibitor of phosphorolysis. Enzyme fluorescence quenching, and concomitant changes in absorption and fluorescence spectra of the two ionic species of m7Guo on binding, showed that both forms are bound by the enzyme, the affinity of the zwitterion being 3-fold lower than that of the cation. Binding of m7Guo is bimodal, i.e., an increase in ligand concentration leads to a decrease in the association constant of the enzyme-ligand complex, typical for negative cooperativity of enzyme-ligand binding, with a Hill constant <1. This is in striking contrast to interaction of the enzyme with the parent Guo, for which the association constant is independent of concentration. The weakly fluorescent N(7)-methylguanine (m7Gua), the product of phosphorolysis of m7Guo, is a competitive non-substrate inhibitor of phosphorolysis (K(i)=8+/-2 microM) and exhibits negative cooperativity on binding to the enzyme at pH 6.9. Quenching of enzyme emission by the ligands is a static process, inasmuch as the mean excited-state lifetime, <tau>=2.7 ns, is unchanged in the presence of the ligands, and the constants K(SV) may therefore be considered as the association constants for the enzyme-ligand complexes. In the pH range 9.5-11 there is an instantaneous reversible decrease in PNP emission of approximately 15%, corresponding to one of the six tyrosine residues per subunit readily accessible to solvent, and OH- ions. Relevance of the overall results to the mechanism of phosphorolysis, and binding of substrates/inhibitors is discussed.

Purine nucleoside phosphorylases: properties, functions, and clinical aspects

The ubiquitous purine nucleoside phosphorylases (PNPs) play a key role in the purine salvage pathway, and PNP deficiency in humans leads to an impairment of T-cell function, usually with no apparent effects on B-cell function. This review updates the properties of the enzymes from eukaryotes and a wide range of prokaryotes, including a tentative classification of the enzymes from various sources, based on three-dimensional structures in the solid state, subunit composition, amino acid sequences, and substrate specificities. Attention is drawn to the compelling need of quantitative experimental data on subunit composition in solution, binding constants, and stoichiometry of binding; order of ligand binding and release; and its possible relevance to the complex kinetics exhibited with some substrates. Mutations responsible for PNP deficiency are described, as well as clinical methods, including gene therapy, for corrections of this usually fatal disease. Substrate discrimination between enzymes from different sources is also being profited from for development of tumour-directed gene therapy. Detailed accounts are presented of design of potent inhibitors, largely nucleosides and acyclonucleosides, their phosphates and phosphonates, particularly of the human erythrocyte enzyme, some with Ki values in nanomolar and picomolar range, intended for induction of the immunodeficient state for clinical applications, such as prevention of host-versus-graft response in organ transplantations. Methods of assay of PNP activity are reviewed. Also described are applications of PNP from various sources as tools for the enzymatic synthesis of otherwise inaccessible therapeutic nucleoside analogues, as coupling enzymes for assays of orthophosphate in biological systems in the micromolar and submicromolar ranges, and for coupled assays of other enzyme systems.

Crystal structure of the purine nucleoside phosphorylase (PNP) from Cellulomonas sp. and its implication for the mechanism of trimeric PNPs

The three-dimensional structure of the trimeric purine nucleoside phosphorylase (PNP) from Cellulomonas sp. has been determined by X-ray crystallography. The binary complex of the enzyme with orthophosphate was crystallized in the orthorhombic space group P212121 with unit cell dimensions a=64.1 A, b=108.9 A, c=119.3 A and an enzymatically active trimer in the asymmetric unit. X-ray data were collected at 4 degrees C using synchrotron radiation (EMBL/DESY, Hamburg). The structure was solved by molecular replacement, with the calf spleen PNP structure as a model, and refined at 2.2 A resolution. The ternary "dead-end" complex of the enzyme with orthophosphate and 8-iodoguanine was obtained by soaking crystals of the binary orthophosphate complex with the very weak substrate 8-iodoguanosine. Data were collected at 100 K with CuKalpha radiation, and the three-dimensional structure refined at 2.4 A resolution. Although the sequence of the Cellulomonas PNP shares only 33 % identity with the calf spleen enzyme, and almost no identity with the hexameric Escherichia coli PNP, all three enzymes have many common structural features, viz. the nine-stranded central beta-sheet, the positions of the active centres, and the geometrical arrangement of the ligands in the active centres. Some similarities of the surrounding helices also prevail. In Cellulomonas PNP, each of the three active centres per trimer is occupied by orthophosphate, and by orthophosphate and base, respectively, and small structural differences between monomers A, B and C are observed. This supports cooperativity between subunits (non-identity of binding sites) rather than existence of more than one binding site per monomer, as previously suggested for binding of phosphate by mammalian PNPs. The phosphate binding site is located between two conserved beta- and gamma-turns and consists of Ser46, Arg103, His105, Gly135 and Ser223, and one or two water molecules. The guanine base is recognized by a zig-zag pattern of possible hydrogen bonds, as follows: guanine N-1...Glu204 O(epsilon1)...guanine NH2...Glu204 O(epsilon2). The exocyclic O6 of the base is bridged via a water molecule to Asn246 N(delta), which accounts for the inhibitory, but lack of substrate, activity of adenosine. An alternative molecular mechanism for catalysis by trimeric PNPs is proposed, in which the key catalytic role is played by Glu204 (Glu201 in the calf and human enzymes), while Asn246 (Asn243 in the mammalian enzymes) supports binding of 6-oxopurines rather than catalysis. This mechanism, in contrast to that previously suggested, is consistent with the excellent substrate properties of N-7 substituted nucleosides, the specificity of trimeric PNPs versus 6-oxopurine nucleosides and the reported kinetic properties of Glu201/Ala and Asn243/Ala point variants of human PNP.

Isolation and characterization of mutations in the Escherichia coli regulatory protein XapR

In this work, the LysR-type protein XapR has been subjected to a mutational analysis. XapR regulates the expression of xanthosine phosphorylase (XapA), a purine nucleoside phosphorylase in Escherichia coli. In the wild type, full expression of XapA requires both a functional XapR protein and the inducer xanthosine. Here we show that deoxyinosine can also function as an inducer in the wild type, although not to the same extent as xanthosine. We have isolated and characterized in detail the mutants that can be induced by other nucleosides as well as xanthosine. Sequencing of the mutants has revealed that two regions in XapR are important for correct interactions between the inducer and XapR. One region is defined by amino acids 104 and 132, and the other region, containing most of the isolated mutations, is found between amino acids 203 and 210. These regions, when modelled into the three-dimensional structure of CysB from Klebsiella aerogenes, are placed close together and are most probably directly involved in binding the inducer xanthosine.

Crystal structure of the ternary complex of E. coli purine nucleoside phosphorylase with formycin B, a structural analogue of the substrate inosine, and phosphate (Sulphate) at 2.1 A resolution

The ternary complex of purine nucleoside phosphorylase from E. coli with formycin B and a sulphate or phosphate ion crystallized in the hexagonal space group P6122 with unit cell dimensions a=123.11, c=241.22 A and three monomers per asymmetric unit. The biologically active hexamer is formed through 2-fold crystallographic symmetry, constituting a trimer of dimers. High-resolution X-ray diffraction data were collected using synchrotron radiation (Daresbury, England). The crystal structure was determined by molecular replacement and refined at 2.1 A resolution to an R-value of 0.196. There is one active centre per monomer, composed of residues belonging to two subunits of one dimer. The phosphate binding site is strongly positively charged and consists of three arginine residues (Arg24, Arg87 and Arg43 from a neighbouring subunit), Ser90 and Gly20. It is occupied by a sulphate or phosphate anion, each oxygen atom of which accepts at least two hydrogen bonds or salt-bridges. The sulphate or phosphate anion is also in direct contact with the ribose moiety of formycin B. The ribose binding site is composed of Ser90, Met180, Glu181 and His4, the latter belonging to the neighbouring subunit. The base binding site is exposed to solvent, and the base is unspecifically bound through a chain of water molecules and aromatic-aromatic interactions. In all monomers the nucleosides are in the high syn conformation about the glycosidic bonds with chi in the range 100 to 130 degrees. The architecture of the active centre is in line with the known broad specificity and the kinetic properties of E. coli PNP.

The crystal structure of Escherichia coli purine nucleoside phosphorylase: a comparison with the human enzyme reveals a conserved topology

BACKGROUND

Purine nucleoside phosphorylase (PNP) from Escherichia coli is a hexameric enzyme that catalyzes the reversible phosphorolysis of 6-amino and 6-oxopurine (2'-deoxy)ribonucleosides to the free base and (2'-deoxy)ribose-1-phosphate. In contrast, human and bovine PNPs are trimeric and accept only 6-oxopurine nucleosides as substrates. The difference in the specificities of these two enzymes has been utilized in gene therapy treatments in which certain prodrugs are cleaved by E. coli PNP but not the human enzyme. The trimeric and hexameric PNPs show no similarity in amino acid sequence, even though they catalyze the same basic chemical reaction. Structural comparison of the active sites of mammalian and E. coli PNPs would provide an improved basis for the design of potential prodrugs that are specific for E. coli PNP.

RESULTS

The crystal structure of E. coli PNP at 2.0 A resolution shows that the overall subunit topology and active-site location within the subunit are similar to those of the subunits from human PNP and E. coli uridine phosphorylase. Nevertheless, even though the overall geometry of the E. coli PNP active site is similar to human PNP, the active-site residues and subunit interactions are strikingly different. In E. coli PNP, the purine- and ribose-binding sites are generally hydrophobic, although a histidine residue from an adjacent subunit probably forms a hydrogen bond with a hydroxyl group of the sugar. The phosphate-binding site probably consists of two main-chain nitrogen atoms and three arginine residues. In addition, the active site in hexameric PNP is much more accessible than in trimeric PNP.

CONCLUSIONS

The structures of human and E. coli PNP define two possible classes of nucleoside phosphorylase, and help to explain the differences in specificity and efficiency between trimeric and hexameric PNPs. This structural data may be useful in designing prodrugs that can be activated by E. coli PNP but not the human enzyme.

Binding of divalent magnesium by Escherichia coli phosphoribosyl diphosphate synthetase

The mechanism of binding of the substrates Mg x ATP and ribose 5-phosphate as well as Mg2+ to the enzyme 5-phospho-D-ribosyl (alpha-1-diphosphate synthetase from Escherichia coli has been analyzed. By use of the competive inhibitors of ATP and ribose 5-phosphate binding, alpha,beta-methylene ATP and (+)-1-alpha,2-alpha,3-alpha-trihydroxy-4-beta-cyclopentanemethanol 5-phosphate, respectively, the binding of Mg2+ and the substrates were determined to occur via a steady state ordered mechanism in which Mg2+ binds to the enzyme first and ribose 5-phosphate binds last. Mg2+ binding to the enzyme prior to the binding of substrates and products indicated a role of Mg2+ in preparing the active site of phosphoribosyl diphosphate synthetase for binding of the highly phosphorylated ligands Mg x ATP and phosphoribosyl diphosphate, as evaluated by analysis of the effects of the inhibitors adenosine and ribose 1,5-bisphosphate. Calcium ions, which inhibit the enzyme even in the presence of high concentrations of Mg2+, appeared to compete with free Mg2+ for binding to its activator site on the enzyme. Analysis of the inhibition of Mg2+ binding by Mg x ADP indicated that Mg x ADP binding to the allosteric site may occur in competition with enzyme bound Mg2+. Ligand binding studies showed that 1 mol of Mg x ATP was bound per mol of phosphoribosyl diphosphate synthetase subunit, which indicated that the allosteric sites of the multimeric enzyme were not made up by inactive catalytic sites.

Binding of phosphate and sulfate anions by purine nucleoside phosphorylase from E. coli: ligand-dependent quenching of enzyme intrinsic fluorescence

Steady-state and time-resolved emission spectroscopy was applied to a study of the binary and ternary complexes of pure E. coli purine nucleoside phosphorylase (PNP) with phosphate (Pi; a substrate) and a close non-substrate analogue (sulfate; SA). The quenching of enzyme fluorescence by Pi was bimodal, best described by two modified Stem-Volmer equations fitted independently for "low" (below 0.5 mM Pi) and "high" (above 0.5 mM Pi) ligand concentrations. At Pi > 0.5 mM, binding is characterized by a fortyfold higher dissociation constant (Kd2 = 1.12 +/- 0.10 mM), i.e. by a lower affinity for phosphate, with a sevenfold lower quenching constant and 1.6-fold higher accessibility. By contrast, the binding of SA, and the resultant fluorescence quenching, was unimodal, with Kd = 1.36 +/- 0.07 mM, comparable to the Kd for Pi at "high" Pi, with a total binding capacity of one sulfate or phosphate group per enzyme subunit. SA proved to be a competitive inhibitor of phosphorolysis with Ki = 1.2 +/- 0.2 mM vs. Pi, hence similar to its Kd. SA at a concentration of 5 mM did not affect the Pi affinity at Pi < 0.5 mM, but led to a reduced affinity and twofold higher Pi binding capacities at Pi > 0.5 mM. The resultant fluorescence quenching by Pi decreased at 5 mM SA, with lower Stern-Volmer constant (KSV) and fractional accessibility (fa) values. Increasing concentrations of Pi reduced the enzyme affinity for SA, characterized by a higher Kd. The Hill model showed negative cooperative binding of Pi in the absence and presence of 5 mM SA with Hill coefficients h = 0.60 +/- 0.01 and h = 0.83 +/- 0.07, respectively. SA exhibited non-cooperative binding in the absence of Pi (h = 1.08 +/- 0.01) and negative cooperative binding in the presence of Pi (h < 1). PNP fluorescence decays were best fitted to a sum of two exponentials, with an average lifetime of 2.40 +/- 0.14 ns unchanged on interaction with quenching ligands, and pointing to static quenching. The overall results are relevant to the properties of PNP from various sources, in particular to the design of potent bisubstrate analogue inhibitors.

Different oligomeric states are involved in the allosteric behavior of uracil phosphoribosyltransferase from Escherichia coli

Uracil phosphoribosyltransferase, catalyzing the formation of UMP and pyrophosphate from uracil and 5-phosphoribosyl-alpha-1-diphosphate (PPRibP), was purified from an overproducing strain of Escherichia coli. GTP was shown to activate the enzyme by reducing K(m) for PPRibP by about fivefold without affecting Vmax. When started by addition of enzyme, the reactions accelerated over an extended period of time, while enzyme solutions incubated first with GTP and PPRibP displayed constant velocities. This indicated that PPRibP and GTP influenced the structure of the enzyme. Gel-filtration and sedimentation analyses showed that the apparent oligomeric state of uracil phosphoribosyltransferase is defined by a dynamic equilibrium between a slowly sedimenting form (dimeric or trimeric) that has only a little activity, and a more highly aggregated form (pentameric or hexameric), which is more active. It appears that the smaller form predominates in the absence of substrates, while the larger form predominates in the presence of GTP and PPRibP. Guanosine-3',5'-bis(diphosphate) was found to activate the enzyme much like GTP.

Identification and characterization of genes (xapA, xapB, and xapR) involved in xanthosine catabolism in Escherichia coli

We have characterized four genes from the 52-min region on the Escherichia coli linkage map. Three of these genes are directly involved in the metabolism of xanthosine, whereas the function of the fourth gene is unknown. One of the genes (xapA) encodes xanthosine phosphorylase. The second gene, named xapB, encodes a polypeptide that shows strong similarity to the nucleoside transport protein NupG. The genes xapA and xapB are located clockwise of a gene identified as xapR, which encodes a positive regulator belonging to the LysR family and is required for the expression of xapA and xapB. The genes xapA and xapB form an operon, and their expression was strictly dependent on the presence of both the XapR protein and the inducer xanthosine. Expression of the xapR gene is constitutive and not autoregulated, unlike the case for many other LysR family proteins. In minicells, the XapB polypeptide was found primarily in the membrane fraction, indicating that XapB is a transport protein like NupG and is involved in the transport of xanthosine.

Cloning of a guanosine-inosine kinase gene of Escherichia coli and characterization of the purified gene product

We attempted to clone an inosine kinase gene of Escherichia coli. A mutant strain which grows slowly with inosine as the sole purine source was used as a host for cloning. A cloned 2.8-kbp DNA fragment can accelerate the growth of the mutant with inosine. The fragment was sequenced, and one protein of 434 amino acids long was found. This protein was overexpressed. The overexpressed protein was purified and characterized. The enzyme had both inosine and guanosine kinase activity. The Vmaxs for guanosine and inosine were 2.9 and 4.9 mumol/min/mg of protein, respectively. The Kms for guanosine and inosine were 6.1 microM and 2.1 mM, respectively. This enzyme accepted ATP and dATP as a phosphate donor but not p-nitrophenyl phosphate. These results show clearly that this enzyme is not a phosphotransferase but a guanosine kinase having low (Vmax/Km) activity with inosine. The sequence of the gene we have cloned is almost identical to that of the gsk gene (K.W. Harlow, P. Nygaard, and B. Hove-Jensen, J. Bacteriol. 177:2236-2240, 1995).

Studies of inhibitor binding to Escherichia coli purine nucleoside phosphorylase using the transferred nuclear Overhauser effect and rotating-frame nuclear Overhauser enhancement

NMR studies of the adenosine analog tubercidin have been carried out in the presence of Escherichia coli purine nucleoside phosphorylase (PNP) in order to characterize the conformation of the enzyme-complexed nucleoside. Although analysis of transferred NOE data at various enzyme/inhibitor ratios indicated a predominantly syn nucleoside conformation in the enzyme-complexed state, the results, particularly the 8(1') and 8(3') NOE interactions, were not quantitatively consistent with any single bound conformation. Dissociation rate constants for the tubercidin-PNP complex were determined based on analysis of chemical shift and line width data as a function of enzyme/inhibitor ratio, Carr-Purcell-Meiboom-Gill measurements of the transverse relaxation rate as a function of pulse rate, and T1 rho experiments as a function of the spin-lock field strength. Dissociation rate constants of 2100 s-1 at 20 degrees C and 1400 s-1 at 10 degrees C were determined using the latter two methods. These rates are sufficiently high to justify the validity of the transferred NOE method for an enzyme as large as PNP. The possible significance of spin diffusion was investigated by the use of the deuterated analog [2'-2H]tubercidin, for which many of the intraligand spin diffusion pathways are eliminated, and by performing a series of transferred ROE experiments. A comparison of data obtained using transferred NOE and ROE measurements provides a basis for separating direct and indirect relaxation pathways. Both approaches indicated that the relatively significant 8(3') NOE interaction was not dominated by spin diffusion. Furthermore, analysis of chemical shift and transverse relaxation data for the tubercidin H-2 resonance gave inconsistent results for the chemical shift of the bound species and was inconsistent with the assumption of a single, bound conformation. These results were interpreted in terms of a 2:1 ratio of a syn, 3'-exo:anti, 3'-endo geometry for bound tubercidin. Ligand competition experiments using 9-deazainosine show that all of the tubercidin TRNOE effects are reversed by addition of the second nucleoside, suggesting that the TRNOE data for tubercidin arise due to interactions at the active sites of PNP rather than as a consequence of nonspecific binding to the enzyme.

Purine nucleoside phosphorylase from bovine lens: purification and properties

Purine nucleoside phosphorylase (purine nucleoside: orthophosphate ribosyltransferase, EC 2.4.2.1) was purified 38,750-fold to apparent electrophoretic homogeneity from bovine ocular lens. The enzyme appears to be a homotrimer with a molecular weight of 97,000, and displays non-linear kinetics with concave downward curvature in double-reciprocal plots with orthophosphate as variable substrate. The analysis of the kinetic parameters of bovine lens purine nucleoside phosphorylase, determined both for the phosphorolytic activity on nucleosides and for ribosylating activity on purine bases, indicates the occurrence of a rapid equilibrium random Bi-Bi mechanism with formation of abortive complexes. The effect of pH on the enzyme activity and on the sensitivity of the enzyme to photoinactivation, as well as the effect of thiol reagents on the enzyme activity and stability, strongly suggest the involvement of histidine and cysteine residues in the active site. From the measurements of the kinetic parameters at different temperatures, heats of formation of the enzyme-substrate complex for guanosine, guanine, orthophosphate and ribose 1-phosphate were determined. Activation energies of 15,250 and 14,650 cal/mol were obtained for phosphorolysis and synthesis of guanosine, respectively.

Formycins A and B and some analogues: selective inhibitors of bacterial (Escherichia coli) purine nucleoside phosphorylase

Formycin B (FB), a moderate inhibitor (Ki approximately 100 microM) of mammalian purine nucleoside phosphorylase (PNP), and formycin A (FA), which is totally inactive vs. the mammalian enzyme, are both effective inhibitors of the bacterial (Escherichia coli) enzyme (Ki approximately 5 microM). Examination of a series of N-methyl analogues of FA and FB led to the finding that N(6)-methyl-FA, virtually inactive vs. the mammalian enzyme, is the most potent inhibitor of E. coli purine nucleoside phosphorylase (Ki approximately 0.3 uM) at neutral pH. Inhibition is competitive not only with respect to Ino, but also relative to 7-methyl-Guo and 7-methyl-Ado, as substrates. Both oxoformycins A and B are relatively poor inhibitors. For the most potent inhibitor, N(6)-methyl-FA, it was shown that the enzyme preferentially binds the neutral, and not the cationic, form. In accordance with this the neutral, but not the cationic form, of the structurally related N(1)-methyl-Ado was found to be an excellent substrate. Reported data on tautomerism of formycins were profited from, and extended, to infer which tautomeric species and ionic forms are the active inhibitors. A commercially available (Sigma) bacterial PNP, of unknown origin, was shown to differ from the E. coli enzyme by its inability to phosphorylase Ado; this enzyme was also resistant to FA and FB. These findings have been extended to provide a detailed comparison of the substrate/inhibitor properties of PNP from various microorganisms.

Purification and characterization of purine nucleoside phosphorylase from Proteus vulgaris

Purine nucleoside phosphorylase was isolated and purified from cell extracts of Proteus vulgaris recovered from spoiling cod fish (Gadus morhua). The molecular weight and isoelectric point of the enzyme were 120,000 +/- 2,000 and pH 6.8. The Michaelis constant for inosine as substrate was 3.9 x 10(-5). Guanosine also served as a substrate (Km = 2.9 x 10(-5). However, the enzyme was incapable of phosphorylizing adenosine. Adenosine proved to be useful as a competitive inhibitor and was used as a ligand for affinity chromatography of purine nucleoside phosphorylase following initial purification steps of gel filtration and ion-exchange chromatography.

Purification and properties of inosine-guanosine phosphorylase from Escherichia coli K-12

A xanthosine-inducible enzyme, inosine-guanosine phosphorylase, has been partially purified from a strain of Escherichia coli K-12 lacking the deo-encoded purine nucleoside phosphorylase. Inosine-guanosine phosphorylase had a particle weight of 180 kilodaltons and was rapidly inactivated by p-chloromercuriphenylsulfonic acid (p-CMB). The enzyme was not protected from inactivation by inosine (Ino), 2'-deoxyinosine (dIno), hypoxanthine (Hyp), Pi, or alpha-D-ribose-1-phosphate (Rib-1-P). Incubating the inactive enzyme with dithiothreitol restored the catalytic activity. Reaction with p-CMB did not affect the particle weight. Inosine-guanosine phosphorylase was more sensitive to thermal inactivation than purine nucleoside phosphorylase. The half-life determined at 45 degrees C between pH 5 and 8 was 5 to 9 min. Phosphate (20 mM) stabilized the enzyme to thermal inactivation, while Ino (1 mM), dIno (1 mM), xanthosine (Xao) (1 mM), Rib-1-P (2 mM), or Hyp (0.05 mM) had no effect. However, Hyp at 1 mM did stabilize the enzyme. In addition, the combination of Pi (20 mM) and Hyp (0.05 mM) stabilized this enzyme to a greater extent than did Pi alone. Apparent activation energies of 11.5 kcal/mol and 7.9 kcal/mol were determined in the phosphorolytic and synthetic direction, respectively. The pH dependence of Ino cleavage or synthesis did not vary between 6 and 8. The substrate specificity, listed in decreasing order of efficiency (V/Km), was: 2'-deoxyguanosine, dIno, guanosine, Xao, Ino, 5'-dIno, and 2',3'-dideoxyinosine. Inosine-guanosine phosphorylase differed from the deo operon-encoded purine nucleoside phosphorylase in that neither adenosine, 2'-deoxyadenosine, nor hypoxanthine arabinoside were substrates or potent inhibitors. Moreover, the E. coli inosine-guanosine phosphorylase was antigenically distinct from the purine nucleoside phosphorylase since it did not react with any of 14 monoclonal antisera or a polyvalent antiserum raised against deo-encoded purine nucleoside phosphorylase.

Computer simulation of purine metabolism

A computer model of purine metabolism, including catabolism, salvage pathways and interconversion among nucleotides, is given. Steady-state rate equations corresponding to metabolic enzymes are written based on information from the literature about their kinetic behaviour. Numerical integration of this set of equations is performed employing selected parameters taken from the literature. After stabilization of purine compound concentrations is reached, simulation of enzyme deficit and enzyme overproduction is carried out. The latter is calculated by varying specified maximum velocities in the numerical integration. A pattern of intermediate metabolite concentrations is found. These results form a basis for the comparison of normal patterns or patterns reflecting the effects of inborn errors of metabolism. The aim of this paper is to demonstrate the usefulness of this computer simulation method in complex metabolism pathways.

Uridine phosphorylase from Escherichia coli B.: kinetic studies on the mechanism of catalysis

Using a highly purified enzyme preparation of uridine phosphorylase from Escherichia coli B, we have performed detailed kinetic studies which include initial-velocity and product-inhibition experiments in the forward and reverse directions of the reaction. These studies indicate a rapid-equilibrium random mechanism for this enzyme with the formation of an enzyme . uracil phosphate abortive complex. Lack of formation of the enzyme . uridine . ribose-1-phosphate abortive complex suggests that the ribosyl moiety of the two ligands compete for the same binding site. The random mechanism is different from the ordered addition of substrates found for uridine phosphorylase from other sources. All the kinetic constants in the forward and reverse directions and the Keq of reaction for E. coli uridine phosphorylase are reported herein.

Correlation of substrate-stabilization patterns with proposed mechanisms for three nucleoside phosphorylases

Substrate-stabilization of uridine phosphorylase (uridine:orthophosphate ribosyltransferase, EC 2.4.2.3), thymidine phosphorylase (thymidine:orthophosphate deoxyribosyltransferase, EC 2.4.2.4) and purine-nucleoside phosphorylase (purine-nucleoside:orthophosphate ribosyltransferase, EC 2.4.2.1) from Escherichia coli was investigated by heat-inactivation experiments. Nucleoside substrates stabilized uridine phosphorylase and purine-nucleoside phosphorylase, but not thymidine phosphorylase. Aglycone substrates stabilized only uridine phosphorylase. Phosphate or pentose-1-phosphate ester substrates stabilized all three enzymes. The appropriate pentose-1-phosphate ester was a more effective stabilizer than was phosphate with all three enzymes. In previous reports dealing with the kinetic analysis of these phosphorylases, sequential mechanisms were proposed. Each enzyme appeared to have different sequence of substrate addition. The substrate-stabilization patterns reported here are consistent with the proposed mechanisms.

Purine nucleoside synthesis, an efficient method employing nucleoside phosphorylases

An improved method for the enzymatic synthesis of purine nucleosides is described. Pyrimidine nucleosides were used as pentosyl donors and two phosphorylases were used as catalysts. One of the enzymes, either uridine phosphorylase (Urd Pase) or thymidine phosphorylase (dThd Pase), catalyzed the phosphorolysis of the pentosyl donor. The other enzyme, purine nucleoside phosphorylase (PN Pase), catalyzed the synthesis of the product nucleoside by utilizing the pentose 1-phosphate ester generated from the phosphorolysis of the pyrimidine nucleoside. Urd Pase, dThd Pase, and PN Pase were separated from each other in extracts of Escherichia coli by titration with calcium phosphate gel. Each enzyme was further purified by ion-exchange chromatography. Factors that affect the stability of these catalysts were studied. The pH optima for the stability of Urd Pase, dThd Pase, and PN Pase were 7.6, 6.5, and 7.4, respectively. The order of relative heat stability was Urd Pase greater than PN Pase greater than dThd Pase. The stability of each enzyme increased with increasing enzyme concentration. This dependence was strongest with dThd Pase and weakest with Urd Pase. Of the substrates tested, the most potent stabilizers of Urd Pase, dThd Pase, and PN Pase were uridine, 2'-deoxyribose 1-phosphate, and ribose 1-phosphate, respectively. Some general guidelines for optimization of yields are given. In a model reaction, optimal product formation was obtained at low phosphate concentrations. As examples of the efficiency of the method, the 2'-deoxyribonucleoside of 6-(dimethylamino)purine and the ribonucleoside of 2-amino-6-chloropurine were prepared in yields of 81 and 76%, respectively.

Two purine nucleoside phosphorylases in Bacillus subtilis. Purification and some properties of the adenosine-specific phosphorylase

Two purine nucleoside phosphorylases (purine-nucleoside:orthophosphate ribosyltransferase, EC 2.4.2.1) were purified from vegetative Bacillus subtilis cells. One enzyme, inosine-guanosine phosphorylase, showed great similarity to the homologous enzyme of Bacillus cereus. It appeared to be a tetramer of molecular weight 95 000. The other enzyme, adenosine phosphorylase, was specific for adenosine and deoxyadenosine. The molecular weight of the native enzyme was 153 000 +/- 10% and the molecular weight of the subunits was 25 500 +/- 5%. This indicates a hexameric structure. The adenosine phosphorylase was inactivated by 10(-3) M p-chloromercuribenzoate and protected against this inactivation by phosphate, adenosine and ribose 1-phosphate.

Purine nucleoside phosphorylase from bovine liver

1. Purine nucleoside phosphorylase (purine nucleoside:orthophosphate ribosyltransferase, E.C. 2.4.2.1) from liver of cattle, Bos taurus, was purified to homogeneity. Some properties of the enzymes from three different bovine tissues were compared and discussed. 2. The enzyme has a molecular weight of 83,000, a sedimentation coefficient of 5.3 S, a Stokes' radius of 3.71 nm, a frictional ratio of 1.30 and a subunit molecular weight of 30,000. 3. Optimal pH for xanthosine degradation is around 5.5, whereas a broad pH activity profile for inosine degradation was observed between 5.0 and 7.5. Lineweaver-Burk plots curved downward at high concentrations of substrates, inosine, phosphate and arsenate.