Kinetic properties and inhibition of the dimeric dUTPase-dUDPase from Leishmania major

Kinetic properties of the dimeric enzyme dUTPase from Leishmania major were studied using a continuous spectrophotometric method. dUTP was the natural substrate and dUMP and PPi the products of the hydrolysis. The trypanosomatid enzyme exhibited a low K(m) value for dUTP (2.11 microM), a k(cat) of 49 s(-1), strict Michaelis-Menten kinetics and is a potent catalyst of dUDP hydrolysis, whereas in other dUTPases described, this compound acts as a competitive inhibitor. Discrimination is achieved for the base and sugar moiety showing specificity constants for different dNTPs similar to those of bacterial, viral, and human enzymes. In the alkaline range, the K(m) for dUTP increases with the dissociation of ionizable groups showing pK(a) values of 8.8, identified as the uracil moiety of dUTP and 10, whereas in the acidic range, K(m) is regulated by an enzyme residue exhibiting a pK(a) of 7.1. Activity is strongly inhibited by the nucleoside triphosphate analog alpha-beta-imido-dUTP, indicating that the enzyme can bind triphosphate analogs. The existence of specific inhibition and the apparent structural and kinetic differences (reflected in different binding strength of dNTPs) with other eukaryotic dUTPases suggest that the present enzyme might be exploited as a target for new drugs against leishmaniasis.     

Effect of an Asp80Ala substitution on the binding of dUTP and dUMP to Trypanosoma cruzi dUTPase

dUTPase (deoxyuridine 5'-triphosphate nucleotide hydrolase) is an enzyme responsible for maintaining low levels of intracellular dUTP and thus prevents uracil incorporation into DNA by DNA polymerases during replication and repair processes. The thermodynamics of binding for both dUTP and dUMP (deoxyuridine 5'-monophosphate) to the D80A mutant form of Trypanosoma cruzi dUTPase have been investigated by fluorescence spectroscopy and high-sensitivity isothermal titration calorimetry. In the presence of magnesium, approximately a 30-fold decrease in the value of the k(cat) and a 15-fold increase in the K(m) for dUTP hydrolysis was calculated while a 5-fold decrease was observed in the affinity for dUMP. In the absence of magnesium, the affinity for dUTP binding was similar for both enzymes while that for dUMP was lowered 3-fold as a consequence of the mutation. Calorimetric titrations in several buffers with different ionization heats rendered similar proton exchanges during the binding of dUMP. Thus, apparently the side chain of Asp 80 does not seem to vary its protonation state during the binding process. The enthalpy change values for the D80A mutant hardly change with temperature and, in addition, were Mg(2+) independent. We conclude that the D80A mutation induces only a slight conformational change in the active site yet results in a significant alteration of nucleotide binding and modifies the ability of the enzyme to discriminate between dUTP and dUMP when magnesium is present.     

The turnover of deoxyuridine triphosphate during the HeLa cell cycle

The synthesis and breakdown of deoxyuridine triphosphate (dUTP) was studied to determine whether a dUTP pool is present at any stage of the HeLa cell cycle. Although cell extracts were found to be capable of phosphorylating dUMP to dUTP, only minimal quantities of intracellular dUMP, dUDP or dUTP could be detected. When thymidylate synthetase was blocked with FUdR the dUMP pool increased but no substantial increase in dUDP or dUTP was seen. A powerful and specific dUTP nucleotidohydrolase (dUTPase, EC3.6.1.23) which hydrolyses dUTP to dUMP and PPi was detected. The activity of this enzyme as well as that of the dUTP synthesizing enzymes was low in G1, rose through S and G2 and reached a maximum just prior to cell division. Pulsing experiments with [5-³H]UdR and [¹⁴C]TdR suggest that the size of the dUTP pool is 1% of the dTTP pool.     

Kinetic and thermodynamic characterization of dUTP hydrolysis by Plasmodium falciparum dUTPase

Deoxyuridine 5'-triphosphate nucleotidohydrolase (dUTPase) catalyzes the hydrolysis of dUTP to dUMP and pyrophosphate and plays an important role in nucleotide metabolism and DNA replication controlling relative cellular levels of dTTP/dUTP, both of which can be incorporated into DNA. Isothermal titration calorimetry has been applied to the determination of the kinetic and thermodynamic parameters of the trimeric Plasmodium falciparum dUTPase, a potential drug target against malaria. The role of divalent ions in binding, and inhibition by different uridine derivatives has been assessed. When dUTP hydrolysis in the presence of EDTA was evaluated, a 105-fold decrease and a 12-fold increase of the k(cat) and K(m) values, respectively, were observed when compared with the dUTP.Mg(2+) complex. Calculation of the activation energy, E(a), and the thermodynamic activation parameters showed that the energetic barrier was ~4-fold higher when Mg(2+) was depleted. Other divalent ions such as Co(2+) or Mn(2+) can substitute the physiological cofactor, however the k(cat) was significantly reduced compared to dUTP.Mg(2+). Binding and inhibition by dU, dUMP, dUDP, and alpha,beta-imido-dUTP were analysed by ITC and compared with data obtained by spectrophotometric methods and binding equilibrium studies. Product inhibition (K(ip) dUMP: 99.34 muM) was insignificant yet K(i) values for dUDP and alpha,beta-imido-dUTP were in the low micromolar range. The effect of ionic strength on protein stability was also monitored. DSC analysis evidenced a slight increase in the unfolding temperature, T(m), with increasing salt concentrations. Moreover, the thermal unfolding pathway in the presence of salt fits adequately to an irreversible two-state model (N(3)-->3D).     

Plasmodium falciparum dUTPase: studies on protein stability and binding of deoxyuridine derivatives

Deoxyuridine triphosphate nucleotidohydrolase (dUTPase), a ubiquitous enzyme preventing a deleterious incorporation of uracil into DNA, has been thought of as a novel target for anticancer and antiviral drug design. The interaction of Plasmodium falciparum dUTPase (PfdUTPase) with deoxyuridine derivatives (dU, dUMP, dUDP and dUpNHpp) has been studied thermodynamically by both isothermal titration and differential scanning calorimetry. ITC shows no cooperativity for the binding of these derivatives. Dependencies in the binding thermodynamic parameters (enthalpy, entropy and Gibbs energy changes) with the number of phosphate groups in the nucleotide are obtained, and from the heat capacity changes no significant conformational changes upon binding are inferred. DSC shows PfdUTPase trimer is very stable but denatures irreversibly, with a more complex denaturation profile than other homologous trimeric dUTPases. The presence of magnesium ions does not influence the denaturation profile, while the presence of deoxyuridine derivatives increases the stability. The increase depends upon nucleotide concentration and type, with dUDP having the greater effect.     

Methylene substitution at the alpha-beta bridging position within the phosphate chain of dUDP profoundly perturbs ligand accommodation into the dUTPase active site

dUTP pyrophosphatase, a preventive DNA repair enzyme, contributes to maintain the appropriate cellular dUTP/dTTP ratio by catalyzing dUTP hydrolysis. dUTPase is essential for viability in bacteria and eukaryotes alike. Identification of species-specific antagonists of bacterial dUTPases is expected to contribute to the development of novel antimicrobial agents. As a first general step, design of dUTPase inhibitors should be based on modifications of the substrate dUTP phosphate chain, as modifications in either base or sugar moieties strongly impair ligand binding. Based on structural differences between bacterial and human dUTPases, derivatization of dUTP-analogous compounds will be required as a second step to invoke species-specific character. Studies performed with dUTP analogues also offer insights into substrate binding characteristics of this important and structurally peculiar enzyme. In this study, alpha,beta-methylene-dUDP was synthesized and its complex with dUTPase was characterized. Enzymatic phosphorylation of this substrate analogue by pyruvate kinase was not possible in contrast to the successful enzymatic phosphorylation of alpha,beta-imino-dUDP. One explanation for this finding is that the different bond angles and the presence of the methylene group may preclude formation of a catalytically competent complex with the kinase. Crystal structure of E. coli dUTPase:alpha,beta-methylene-dUDP and E. coli dUTPase:dUDP:Mn complexes were determined and analyzed in comparison with previous data. Results show that the "trans" alpha-phosphate conformation of alpha,beta-methylene-dUDP differs from the catalytically competent "gauche" alpha-phosphate conformation of the imino analogue and the oxo substrate, manifested in the shifted position of the alpha-phosphorus by more than 3 A. The three-dimensional structures determined in this work show that the binding of the methylene analogue with the alpha-phosphorus in the "gauche" conformation would result in steric clash of the methylene group with the protein atoms. In addition, the metal ion cofactor was not bound in the crystal of the complex with the methylene analogue while it was clearly visible as coordinated to dUDP, arguing that the altered phosphate chain conformation also perturbs metal ion complexation. Isothermal calorimetry titrations indicate that the binding affinity of alpha,beta-methylene-dUDP toward dUTPase is drastically decreased when compared with that of dUDP. In conclusion, the present data suggest that while alpha,beta-methylene-dUDP seems to be practically nonhydrolyzable, it is not a strong binding inhibitor of dUTPase probably due to the altered binding mode of the phosphate chain. Results indicate that in some cases methylene analogues may not faithfully reflect the competent substrate ligand properties, especially if the methylene hydrogens are in steric conflict with the protein.     

Identification and partial characterization of rabbit brain deoxyuridine 5′-triphosphatase

Adult rabbit brain contains the enzymatic machinery to convert deoxyuridine to deoxyuridine triphosphate (dUTP). Although dUTP as dUMP can be readily incorporated into DNA in place of thymidine monophosphate, we detected no (3H)dUMP in newly synthesized (3H)DNA in adult rabbit brain after the intraventricular injection of (3H)deoxyuridine. Only (3H)thymidine was detected. The probable explanation for the lack of incorporation of uracil into adult rabbit brain DNA is the presence of a specific, high affinity dUTPase which converts dUTP to dUMP and PP. After homogenization and ammonium sulfate fractionation of adult rabbit brain (35 to 75% saturation), a high affinity, specific dUTPase was detected in the dialyzed enzyme preparation. The Km and Vmax of the dUTPase were 0.2 microM and 36 pmol/mg protein/min, respectively. No high affinity dUTPase activity was detectable in liver. In brain, another enzyme hydrolyzed dUTP and dTTP (NTPase( to their respective diphosphates. NTPase, unlike dUTPase, was not sensitive to heating at 65 degrees C for five minutes. Thus, brain, like other tissues, contains a high affinity, specific dUTPase presumably to "sanitize" the cells of dUTP and, thus, protect the integrity of newly synthesized DNA.     

Structure/function analysis of a dUTPase: catalytic mechanism of a potential chemotherapeutic target.

dUTP pyrophosphatase catalyses hydrolysis of deoxyuridine triphosphate (dUTP) to deoxyuridine monophosphate (dUMP) and inorganic pyrophosphate (PPi). Elimination of dUTP is vital since its misincorporation into DNA by DNA polymerases can initiate a damaging iterative repair and misincorporation cycle, resulting in DNA fragmentation and cell death. The anti-tumour activity of folate agonists and thymidylate synthase inhibitors is thought to rely on dUTP misincorporation. Furthermore, retroviral cDNA production may be particularly susceptible to the effects of dUTP misincorporation by virtue of the error-prone nature of reverse trans criptase. Consequently, dUTPase activity is an ideal point of intervention in both chemotherapy and anti-retroviral therapy. In particular, the dUTPase encoded by a human endogenous retrovirus (HERV-K) has been suggested to complement HIV infection and so is an attractive target for specific inhibition. Hence, we used site photoaffinity labelling, site-directed mutagenesis and molecular modelling to assign catalytic roles to the conserved amino acid residues in the active site of the HERV-K dUTPase and to identify structural differences with other dUTPase enzymes. We found that dUTP photoaffinity labelling was specific for a beta-hairpin motif in HERV-K dUTPase. Mutagenesis of aspartate residues Asp84 and 86 to asparagine within this beta-hairpin showed the carboxylate moiety of both residues was required for catalysis but not for dUTP binding. An increase in the pKa of both aspartate residues brought about by substitution of a serine residue with a glutamate residue adjacent to the aspartate residues increased activity by a factor of 1.67 at pH 8.0, implicating general base catalysis as the enzyme's catalytic mechanism. Conservative mutagenesis of Tyr87 to Phe resulted in a sevenfold reduction of dUTPase activity and a 3.3-fold reduction in binding activity, whilst substitution with an isoleucine residue totally abolished both catalytic activity and dUTP binding, suggesting that binding/activity is dependent on an aromatic side-chain at the base of the hairpin. Comparison of a homology-based three-dimensional model structure of HERV-K dUTPase with a crystallographic structure of the human dUTPase revealed displacement of a conserved alpha-helix in the HERV-K enzyme causing expansion of the HERV-K active site. This expansion may be responsible for the ability of the HERV-K enzyme to hydrolyse dTTP and bind the bulkier dNTPs in contrast to the majority of dUTPases which are highly specific for dUTP. Knowledge of the dUTPase catalytic mechanism and the distinctive topography of the HERV-K active site provides a molecular basis for the design of HERV-K dUTPase-specific inhibitors.     

The crystal structure of the Leishmania major deoxyuridine triphosphate nucleotidohydrolase in complex with nucleotide analogues, dUMP, and deoxyuridine

Members of the Leishmania genus are the causative agents of the life-threatening disease leishmaniasis. New drugs are being sought due to increasing resistance and adverse side effects with current treatments. The knowledge that dUTPase is an essential enzyme and that the all α-helical dimeric kinetoplastid dUTPases have completely different structures compared with the trimeric β-sheet type dUTPase possessed by most organisms, including humans, make the dimeric enzymes attractive drug targets. Here, we present crystal structures of the Leishmania major dUTPase in complex with substrate analogues, the product dUMP and a substrate fragment, and of the homologous Campylobacter jejuni dUTPase in complex with a triphosphate substrate analogue. The metal-binding properties of both enzymes are shown to be dependent upon the ligand identity, a previously unseen characteristic of this family. Furthermore, structures of the Leishmania enzyme in the presence of dUMP and deoxyuridine coupled with tryptophan fluorescence quenching indicate that occupation of the phosphate binding region is essential for induction of the closed conformation and hence for substrate binding. These findings will aid in the development of dUTPase inhibitors as potential new lead anti-trypanosomal compounds.     

The crystal structure of a complex of Campylobacter jejuni dUTPase with substrate analogue sheds light on the mechanism and suggests the "basic module" for dimeric d(C/U)TPases

The crystal structure of the dUTPase from the important gastric pathogen Campylobacter jejuni has been solved at 1.65 A spacing. This essential bacterial enzyme is the second representative of the new family of dimeric dUTPases to be structurally characterised. Members of this family have a novel all-alpha fold and are unrelated to the all-beta dUTPases of the majority of organisms including eukaryotes such as humans, bacteria such as Escherichia coli, archaea like Methanococcus jannaschii and animal viruses. Therefore, dimeric dUTPases can be considered as candidate drug targets. The X-ray structure of the C.jejuni dUTPase in complex with the non-hydrolysable substrate analogue dUpNHp allows us to define the positions of three catalytically significant phosphate-binding magnesium ions and provides a starting point for a detailed understanding of the mechanism of dUTP/dUDP hydrolysis by dimeric dUTPases. Indeed, a water molecule present in the structure is ideally situated to act as the attacking nucleophile during hydrolysis. A comparison of the dUTPases from C.jejuni and Trypanosoma cruzi reveals a common fold with certain distinct features, both in the rigid and mobile domains as defined in the T.cruzi structure. Homologues of the C.jejuni dUTPase have been identified in several other bacteria and bacteriophages, including the dCTPase of phage T4. Sequence comparisons of these proteins define a new superfamily of d(C/U)TPases that includes three distinct enzyme families: (1) dUTPases in trypanosomatides, C.jejuni and several other Gram-negative bacteria, (2) predicted dUTPases in various Gram-positive bacteria and their phages, and (3) dCTP/dUTPases in enterobacterial T4-like phages. All these enzymes share a basic module that consists of two alpha-helices from the rigid domain, two helices from the mobile domain and connecting loops. These results in concert with a number of conserved residues responsible for interdomain cross-talk provide valuable insight towards rational drug design.     

A bifunctional dCTP deaminase-dUTP nucleotidohydrolase from the hyperthermophilic archaeon Methanocaldococcus jannaschii

By the sequential action of dCTP deaminase and dUTPase, dCTP is converted to dUMP, the precursor of thymidine nucleotides. In addition, dUTPase has an essential role as a safeguard against uracil incorporation in DNA. The putative dCTP deaminase (MJ0430) and dUTPase (MJ1102) from the hyperthermophilic archaeon Methanocaldococcus jannaschii were overproduced in Escherichia coli. Unexpectedly, we found the MJ0430 protein capable of both reactions, i.e. hydrolytic deamination of the cytosine ring and hydrolytic cleavage of the phosphoanhydride bond between the alpha- and beta-phosphates. When the reaction was followed by thin layer chromatography using [3H]dCTP as substrate, dUMP and not dUTP was identified as a reaction product. In the presence of unlabeled dUTP, which acted as an inhibitor, no label was transferred from [3H]dCTP to the pool of dUTP. This finding strongly suggests that the two consecutive steps of the reaction are tightly coupled within the enzyme. The hitherto unknown bifunctionality of the MJ0430 protein appears beneficial for the cells because the toxic intermediate dUTP is never released. The MJ0430 protein also catalyzed the hydrolysis of dUTP to dUMP but with a low affinity for the substrate (Km >100 micro m). According to limited proteolysis, the C-terminal residues constitute a flexible region. The other protein investigated, MJ1102, is a specific dUTPase with a Km for dUTP (0.4 micro m) comparable in magnitude with that found for previously characterized dUTPases. Its physiological function is probably to degrade dUTP derived from other reactions in nucleotide metabolism.     

Structure and activity of the Saccharomyces cerevisiae dUTP pyrophosphatase DUT1, an essential housekeeping enzyme

Genomes of all free-living organisms encode the enzyme dUTPase (dUTP pyrophosphatase), which plays a key role in preventing uracil incorporation into DNA. In the present paper, we describe the biochemical and structural characterization of DUT1 (Saccharomyces cerevisiae dUTPase). The hydrolysis of dUTP by DUT1 was strictly dependent on a bivalent metal cation with significant activity observed in the presence of Mg2+, Co2+, Mn2+, Ni2+ or Zn2+. In addition, DUT1 showed a significant activity against another potentially mutagenic nucleotide: dITP. With both substrates, DUT1 demonstrated a sigmoidal saturation curve, suggesting a positive co-operativity between the subunits. The crystal structure of DUT1 was solved at 2 ? resolution (1 ?=0.1 nm) in an apo state and in complex with the non-hydrolysable substrate α,β-imido dUTP or dUMP product. Alanine-replacement mutagenesis of the active-site residues revealed seven residues important for activity including the conserved triad Asp87/Arg137/Asp85. The Y88A mutant protein was equally active against both dUTP and UTP, indicating that this conserved tyrosine residue is responsible for discrimination against ribonucleotides. The structure of DUT1 and site-directed mutagenesis support a role of the conserved Phe142 in the interaction with the uracil base. Our work provides further insight into the molecular mechanisms of substrate selectivity and catalysis of dUTPases.     

Structural and functional insights into DR2231 protein, the MazG-like nucleoside triphosphate pyrophosphohydrolase from Deinococcus radiodurans

Deinococcus radiodurans is among the very few bacterial species extremely resistant to ionizing radiation, UV light, oxidizing agents, and cycles of prolonged desiccation. The proteome of D. radiodurans reflects the evolutionary pressure exerted by chronic exposure to (nonradioactive) forms of DNA and protein damage. A clear example of this adaptation is the overrepresentation of protein families involved in the removal of non-canonical nucleoside triphosphates (NTPs) whose incorporation into nascent DNA would promote mutagenesis and DNA damage. The three-dimensional structure of the DR2231 protein has been solved at 1.80 Å resolution. This protein had been classified as an all-α-helical MazG-like protein. The present study confirms that it holds the basic structural module characteristic of the MazG superfamily; two helices form a rigid domain, and two helices form a mobile domain and connecting loops. Contrary to what is known of MazG proteins, DR2231 protein shows a functional affinity with dUTPases. Enzymatic and isothermal calorimetry assays have demonstrated high specificity toward dUTP but an inability to hydrolyze dTTP, a typical feature of dUTPases. Co-crystallization with the product of hydrolysis, dUMP, in the presence of magnesium or manganese cations, suggests similarities with the dUTP/dUDP hydrolysis mechanism reported for dimeric dUTPases. The genome of D. radiodurans encodes for all enzymes required for dTTP synthesis from dCMP, thus bypassing the need of a dUTPase. We postulate that DR2231 protein is not essential to D. radiodurans and rather performs “house-cleaning” functions within the framework of oxidative stress response. We further propose DR2231 protein as an evolutionary precursor of dimeric dUTPases.     

The monomeric dUTPase from Epstein-Barr virus mimics trimeric dUTPases

Deoxyuridine 5'-triphosphate pyrophosphatases (dUTPases) are ubiquitous enzymes cleaving dUTP into dUMP and pyrophosphate. They occur as monomeric, dimeric, or trimeric molecules. The trimeric and monomeric enzymes both contain the same five characteristic sequence motifs but in a different order, whereas the dimeric enzymes are not homologous. Monomeric dUTPases only occur in herpesviruses, such as Epstein-Barr virus (EBV). Here, we describe the crystal structures of EBV dUTPase in complex with the product dUMP and a substrate analog alpha,beta-imino-dUTP. The molecule consists of three domains forming one active site that has a structure extremely similar to one of the three active sites of trimeric dUTPases. The three domains functionally correspond to the subunits of the trimeric form. Domains I and II have the dUTPase fold, but they differ considerably in the regions that are not involved in the formation of the unique active site, whereas domain III has only little secondary structure.     

Structural basis for recognition and catalysis by the bifunctional dCTP deaminase and dUTPase from Methanococcus jannaschii

Potentially mutagenic uracil-containing nucleotide intermediates are generated by deamination of dCTP, either spontaneously or enzymatically as the first step in the conversion of dCTP to dTTP. dUTPases convert dUTP to dUMP, thus avoiding the misincorporation of dUTP into DNA and creating the substrate for the next enzyme in the dTTP synthetic pathway, thymidylate synthase. Although dCTP deaminase and dUTPase activities are usually found in separate but homologous enzymes, the hyperthermophile Methanococcus jannaschii has an enzyme, DCD-DUT, that harbors both dCTP deaminase and dUTP pyrophosphatase activities. DCD-DUT has highest activity on dCTP, followed by dUTP, and dTTP inhibits both the deaminase and pyrophosphatase activities. To help clarify structure-function relationships for DCD-DUT, we have determined the crystal structure of the wild-type DCD-DUT protein in its apo form to 1.42A and structures of DCD-DUT in complex with dCTP and dUTP to resolutions of 1.77A and 2.10A, respectively. To gain insights into substrate interactions, we complemented analyses of the experimentally defined weak density for nucleotides with automated docking experiments using dCTP, dUTP, and dTTP. DCD-DUT is a hexamer, unlike the homologous dUTPases, and its subunits contain several insertions and substitutions different from the dUTPase beta barrel core that likely contribute to dCTP specificity and deamination. These first structures of a dCTP deaminase reveal a probable role for an unstructured C-terminal region different from that of the dUTPases and possible mechanisms for both bifunctional enzyme activity and feedback inhibition by dTTP.     

Depletion of dimeric all-alpha dUTPase induces DNA strand breaks and impairs cell cycle progression in Trypanosoma brucei

The enzyme deoxyuridine 5'-triphosphate nucleotidohydrolase (dUTPase) is responsible for the control of intracellular levels of dUTP thus controlling the incorporation of uracil into DNA during replication. Trypanosomes and certain eubacteria contain a dimeric dUTP-dUDPase belonging to the recently described superfamily of all-alpha NTP pyrophosphatases which bears no resemblance with typical eukaryotic trimeric dUTPases and presents unique properties regarding substrate specificity and product inhibition. While the biological trimeric enzymes have been studied in detail and the human enzyme has been proposed as a promising novel target for anticancer chemotherapeutic strategies, little is known regarding the biological function of dimeric proteins. Here, we show that in Trypanosoma brucei, the dimeric dUTPase is a nuclear enzyme and that down-regulation of activity by RNAi greatly reduces cell proliferation and increases the intracellular levels of dUTP. Defects in growth could be partially reverted by the addition of exogenous thymidine. dUTPase-depleted cells presented hypersensitivity to methotrexate, a drug that increases the intracellular pools of dUTP, and enhanced uracil-DNA glycosylase activity, the first step in base excision repair. The knockdown of activity produces numerous DNA strand breaks and defects in both S and G2/M progression. Multiple parasites with a single enlarged nucleus were visualized together with an enhanced population of anucleated cells. We conclude that dimeric dUTPases are strongly involved in the control of dUTP incorporation and that adequate levels of enzyme are indispensable for efficient cell cycle progression and DNA replication.     

Deoxyuridine triphosphate nucleotidohydrolase: distribution of the enzyme in various rat tissues

The distribution of deoxyuridine triphosphate nucleotidohydrolase (dUTPase) [EC 3.6.1.23] in the cytosol of various rat tissues was investigated by measuring the enzyme activity and by immunochemical analyses. Among nine rat tissues, thymus, and spleen showed the highest activities of the enzyme per gram of tissue, while intestine, stomach, lung and liver showed very low levels. Rabbit antibodies directed against purified dUTPase of anemic rat spleen showed reactivity with partially purified dUTPases from other rat tissues such as thymus, testis, or regenerating liver. Immunotitration and immunoblot experiments also indicated that the dUTPases in various rat tissues had very similar antigenicity and apparently the same subunit molecular size (Mr = 19,500), suggesting that the enzyme lacks organ-specificity. Immunoblot analysis of dUTPase protein with crude extracts from various rat tissues showed a similar distribution to that of the enzyme activity. No immuno-reactive band corresponding to the dUTPase was detected in intestine, although intestinal mucosa has been recognized as an actively proliferating tissue.     

Chlorella virus-encoded deoxyuridine triphosphatases exhibit different temperature optima

A putative deoxyuridine triphosphatase (dUTPase) gene from chlorella virus PBCV-1 was cloned, and the recombinant protein was expressed in Escherichia coli. The recombinant protein has dUTPase activity and requires Mg(2+) for optimal activity, while it retains some activity in the presence of other divalent cations. Kinetic studies of the enzyme revealed a K(m) of 11.7 microM, a turnover k(cat) of 6.8 s(-1), and a catalytic efficiency of k(cat)/K(m) = 5.8 x 10(5) M(-1) s(-1). dUTPase genes were cloned and expressed from two other chlorella viruses IL-3A and SH-6A. The two dUTPases have similar properties to PBCV-1 dUTPase except that IL-3A dUTPase has a lower temperature optimum (37 degrees C) than PBCV-1 dUTPase (50 degrees C). The IL-3A dUTPase differs from the PBCV-1 enzyme by nine amino acids, including two amino acid substitutions, Glu81-->Ser81 and Thr84-->Arg84, in the highly conserved motif III of the proteins. To investigate the difference in temperature optima between the two enzymes, homology modeling and docking simulations were conducted. The results of the simulation and comparisons of amino acid sequence suggest that adjacent amino acids are important in the temperature optima. To confirm this suggestion, three site-directed amino acid substitutions were made in the IL-3A enzyme: Thr84-->Arg84, Glu81-->Ser81, and Glu81-->Ser81 plus Thr84-->Arg84. The single substitutions affected the optimal temperature for enzyme activity. The temperature optimum increased from 37 to 55 degrees C for the enzyme containing the two amino acid substitutions. We postulate that the change in temperature optimum is due to reduction in charge and balkiness in the active cavity that allows more movement of the ligand and protein before the enzyme and substrate complex is formed.     

African Swine Fever Virus dUTPase Is a Highly Specific Enzyme Required for Efficient Replication in Swine Macrophages

The African swine fever virus (ASFV) gene E165R, which is homologous to dUTPases, has been characterized. A multiple alignment of dUTPases showed the conservation in ASFV dUTPase of the motifs that define this protein family. A biochemical analysis of the purified recombinant enzyme showed that the virus dUTPase is a trimeric, highly specific enzyme that requires a divalent cation for activity. The enzyme is most probably complexed with Mg(2+), the preferred cation, and has an apparent K(m) for dUTP of 1 microM. Northern and Western blotting, as well as immunofluorescence analyses, indicated that the enzyme is expressed at early and late times of infection and is localized in the cytoplasm of the infected cells. On the other hand, an ASFV dUTPase-deletion mutant (vDeltaE165R) has been obtained. Growth kinetics showed that vDeltaE165R replicates as efficiently as parental virus in Vero cells but only to 10% or less of parental virus in swine macrophages. Our results suggest that the dUTPase activity is dispensable for virus replication in dividing cells but is required for productive infection in nondividing swine macrophages, the natural host cell for the virus. The viral dUTPase may play a role in lowering the dUTP concentration in natural infections to minimize misincorporation of deoxyuridine into the viral DNA and ensure the fidelity of genome replication.     

The crystal structure of Trypanosoma cruzi dUTPase reveals a novel dUTP/dUDP binding fold

dUTPase is an essential enzyme involved with nucleotide metabolism and replication. We report here the X-ray structure of Trypanosoma cruzi dUTPase in its native conformation and as a complex with dUDP. These reveal a novel protein fold that displays no structural similarities to previously described dUTPases. The molecular unit is a dimer with two active sites. Nucleotide binding promotes extensive structural rearrangements, secondary structure remodeling, and rigid body displacements of 20 A or more, which effectively bury the substrate within the enzyme core for the purpose of hydrolysis. The molecular complex is a trapped enzyme-substrate arrangement which clearly demonstrates structure-induced specificity and catalytic potential. This enzyme is a novel dUTPase and therefore a potential drug target in the treatment of Chagas' disease.