Structures of dCTP deaminase from Escherichia coli with bound substrate and product: reaction mechanism and determinants of mono- and bifunctionality for a family of enzymes

dCTP deaminase (EC 3.5.4.13) catalyzes the deamination of dCTP forming dUTP that via dUTPase is the main pathway providing substrate for thymidylate synthase in Escherichia coli and Salmonella typhimurium. dCTP deaminase is unique among nucleoside and nucleotide deaminases as it functions without aid from a catalytic metal ion that facilitates preparation of a water molecule for nucleophilic attack on the substrate. Two active site amino acid residues, Arg(115) and Glu(138), were identified by mutational analysis as important for activity in E. coli dCTP deaminase. None of the mutant enzymes R115A, E138A, or E138Q had any detectable activity but circular dichroism spectra for all mutant enzymes were similar to wild type suggesting that the overall structure was not changed. The crystal structures of wild-type E. coli dCTP deaminase and the E138A mutant enzyme have been determined in complex with dUTP and Mg(2+), and the mutant enzyme also with the substrate dCTP and Mg(2+). The enzyme is a third member of the family of the structurally related trimeric dUTPases and the bifunctional dCTP deaminase-dUTPase from Methanocaldococcus jannaschii. However, the C-terminal fold is completely different from dUTPases resulting in an active site built from residues from two of the trimer subunits, and not from three subunits as in dUTPases. The nucleotides are well defined as well as Mg(2+) that is tridentately coordinated to the nucleotide phosphate chains. We suggest a catalytic mechanism for the dCTP deaminase and identify structural differences to dUTPases that prevent hydrolysis of the dCTP triphosphate.     

Mutational analysis of the nucleotide binding site of Escherichia coli dCTP deaminase

In Escherichia coli and Salmonella typhimurium about 80% of the dUMP used for dTMP synthesis is derived from deamination of dCTP. The dCTP deaminase produces dUTP that subsequently is hydrolyzed by dUTPase to dUMP and diphosphate. The dCTP deaminase is regulated by dTTP that inhibits the enzyme by binding to the active site and induces an inactive conformation of the trimeric enzyme. We have analyzed the role of residues previously suggested to play a role in catalysis. The mutant enzymes R115Q, S111C, S111T and E138D were all purified and analyzed for activity. Only S111T and E138D displayed detectable activity with a 30- and 140-fold reduction in k_cat, respectively. Furthermore, S111T and E138D both showed altered dTTP inhibition compared to wild-type enzyme. S111T was almost insensitive to the presence of dTTP. With the E138D enzyme the dTTP dependent increase in cooperativity of dCTP saturation was absent, although the dTTP inhibition itself was still cooperative. Modeling of the active site of the S111T enzyme indicated that this enzyme is restricted in forming the inactive dTTP binding conformer due to steric hindrance by the additional methyl group in threonine. The crystal structure of E138D in complex with dUTP showed a hydrogen bonding network in the active site similar to wild-type enzyme. However, changes in the hydrogen bond lengths between the carboxylate and a catalytic water molecule as well as a slightly different orientation of the pyrimidine ring of the bound nucleotide may provide an explanation for the reduced activity.     

Regulation of dCTP deaminase from Escherichia coli by nonallosteric dTTP binding to an inactive form of the enzyme

The trimeric dCTP deaminase produces dUTP that is hydrolysed to dUMP by the structurally closely related dUTPase. This pathway provides 70-80% of the total dUMP as a precursor for dTTP. Accordingly, dCTP deaminase is regulated by dTTP, which increases the substrate concentration for half-maximal activity and the cooperativity of dCTP saturation. Likewise, increasing concentrations of dCTP increase the cooperativity of dTTP inhibition. Previous structural studies showed that the complexes of inactive mutant protein, E138A, with dUTP or dCTP bound, and wild-type enzyme with dUTP bound were all highly similar and characterized by having an ordered C-terminal. When comparing with a new structure in which dTTP is bound to the active site of E138A, the region between Val120 and His125 was found to be in a new conformation. This and the previous conformation were mutually exclusive within the trimer. Also, the dCTP complex of the inactive H121A was found to have residues 120-125 in this new conformation, indicating that it renders the enzyme inactive. The C-terminal fold was found to be disordered for both new complexes. We suggest that the cooperative kinetics are imposed by a dTTP-dependent lag of product formation observed in presteady-state kinetics. This lag may be derived from a slow equilibration between an inactive and an active conformation of dCTP deaminase represented by the dTTP complex and the dUTP/dCTP complex, respectively. The dCTP deaminase then resembles a simple concerted system subjected to effector binding, but without the use of an allosteric site.     

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.     

Mechanism of dTTP inhibition of the bifunctional dCTP deaminase:dUTPase encoded by Mycobacterium tuberculosis

Recombinant deoxycytidine triphosphate (dCTP) deaminase from Mycobacterium tuberculosis was produced in Escherichia coli and purified. The enzyme proved to be a bifunctional dCTP deaminase:deoxyuridine triphosphatase. As such, the M. tuberculosis enzyme is the second bifunctional enzyme to be characterised and provides evidence for bifunctionality of dCTP deaminase occurring outside the Archaea kingdom. A steady-state kinetic analysis revealed that the affinity for dCTP and deoxyuridine triphosphate as substrates for the synthesis of deoxyuridine monophosphate were very similar, a result that contrasts that obtained previously for the archaean Methanocaldococcus jannaschii enzyme, which showed approximately 10-fold lower affinity for deoxyuridine triphosphate than for dCTP.The crystal structures of the enzyme in complex with the inhibitor, thymidine triphosphate, and the apo form have been solved. Comparison of the two shows that upon binding of thymidine triphosphate, the disordered C-terminal arranges as a lid covering the active site, and the enzyme adapts an inactive conformation as a result of structural changes in the active site. In the inactive conformation dephosphorylation cannot take place due to the absence of a water molecule otherwise hydrogen-bonded to O2 of the α-phosphate.     

A double role for a strictly conserved serine: further insights into the dUTPase catalytic mechanism

Ser72 at the active site of the Escherichia coli dUTPase has been mutated to an alanine, and the properties of the mutant have been investigated. The serine is absolutely conserved among the monomeric and trimeric dUTPases (including the bifunctional dCTP deaminase:dUTPases), and it has been proposed to promote catalysis by balancing negative charge at the oxygen that bridges the alpha- and beta-phosphorus of the substrate. In all reported complexes of dUTPases with the substrate analogue alpha,beta-imido-dUTP.Mg, the serine beta-OH is indeed hydrogen bonded to the alpha,beta-bridging nitrogen of the analogue. However, in the complex of the Asp90 --> Asn mutant dUTPase with the true substrate dUTP.Mg, the serine beta-OH points in the opposite direction and may form a hydrogen bond to Asn84 at the bottom of the pyrimidine pocket. Here we show that the replacement of the beta-OH by hydrogen reduces k cat from 5.8 to 0.008 s (-1) but also k -1 , the rate of substrate dissociation, from 6.2 to 0.1 s (-1) ( K M = 6 x 10 (-9) M). We conclude that the serine beta-OH exercises both ground state (GS) destabilization and transition state (TS) stabilization, effects not usually linked to a single residue. With experimental support, we argue that the beta-OH destabilizes the GS by imposing conformational constraints on the enzyme and that formation of the TS depends on a rotation of the serine side chain that not only relieves the constraints but brings the beta-OH into a position where it can electrostatically stabilize the TS. This rotation would also allow the beta-OH to promote both deamination and hydrolysis in the bifunctional deaminases. We find that the E. coli dUTPase does not catalyze the hydrolysis of the alpha,beta-imido-dUTP.Mg, suggesting that the analogue provides the hydrogen in the bond to the serine beta-OH.     

The Methanococcus jannaschii dCTP deaminase is a bifunctional deaminase and diphosphatase

Most bacteria produce the dUMP precursor for thymine nucleotide biosynthesis using two enzymes: a dCTP deaminase catalyzes the formation of dUTP and a dUTP diphosphatase catalyzes pyrophosphate release. Although these two hydrolytic enzymes appear to catalyze very different reactions, they are encoded by homologous genes. The hyperthermophilic archaeon Methanococcus jannaschii has two members of this gene family. One gene, at locus MJ1102, encodes a dUTP diphosphatase, which can scavenge deoxyuridine nucleotides that inhibit archaeal DNA polymerases. The second gene, at locus MJ0430, encodes a novel dCTP deaminase that releases dUMP, ammonia, and pyrophosphate. Therefore this enzyme can singly catalyze both steps in dUMP biosynthesis, precluding the formation of free, mutagenic dUTP. Besides differing from the previously characterized Salmonella typhimurium dCTP deaminase in its reaction products, this archaeal enzyme has a higher affinity for dCTP and its steady-state turnover is faster than the bacterial enzyme. Kinetic studies suggest: 1) the archaeal enzyme specifically recognizes dCTP; 2) dCTP deamination and dUTP diphosphatase activities occur independently at the same active site, and 3) both activities depend on Mg(2+). The bifunctional activity of this M. jannaschii enzyme illustrates the evolution of a suprafamily of related enzymes that catalyze mechanistically distinct reactions.     

Structure of the bifunctional dCTP deaminase-dUTPase from Methanocaldococcus jannaschii and its relation to other homotrimeric dUTPases

The bifunctional dCTP deaminase-dUTPase (DCD-DUT) from Methanocaldococcus jannaschii catalyzes the deamination of the cytosine moiety in dCTP and the hydrolysis of the triphosphate moiety forming dUMP, thereby preventing uracil from being incorporated into DNA. The crystal structure of DCD-DUT has been determined to 1.88-A resolution and represents the first known structure of an enzyme catalyzing dCTP deamination. The functional form of DCD-DUT is a homotrimer wherein the subunits are composed of a central distorted beta-barrel surrounded by two beta-sheets and four helices. The trimeric DCD-DUT shows structural similarity to trimeric dUTPases at the tertiary and quaternary levels. There are also additional structural elements in DCD-DUT compared with dUTPase because of a longer primary structure. Four of the five conserved sequence motifs that create the active sites in dUTPase are found in structurally equivalent positions in DCD-DUT. The last 25 C-terminal residues of the 204-residue-long DCD-DUT are not visible in the electron density map, but, analogous to dUTPases, the C terminus is probably ordered, closing the active site upon catalysis. Unlike other enzymes catalyzing the deamination of cytosine compounds, DCD-DUT is not exploiting an enzyme-bound metal ion such as zinc or iron for nucleophile generation. The active site contains two water molecules that are engaged in hydrogen bonds to the invariant residues Ser118, Arg122, Thr130, and Glu145. These water molecules are potential nucleophile candidates in the deamination reaction.     

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.     

Active site of mycobacterial dUTPase: structural characteristics and a built-in sensor

dUTPases are essential to eliminate dUTP for DNA integrity and provide dUMP for thymidylate biosynthesis. Mycobacterium tuberculosis apparently lacks any other thymidylate biosynthesis pathway, therefore dUTPase is a promising antituberculotic drug target. Crystal structure of the mycobacterial enzyme in complex with the isosteric substrate analog, α,β-imido-dUTP and Mg²⁺ at 1.5 Å resolution was determined that visualizes the full-length C-terminus, previously not localized. Interactions of a conserved motif important in catalysis, the Mycobacterium-specific five-residue-loop insert and C-terminal tetrapeptide could now be described in detail. Stacking of C-terminal histidine upon the uracil moiety prompted replacement with tryptophan. The resulting sensitive fluorescent sensor enables fast screening for binding of potential inhibitors to the active site. K_d for α,β-imido-dUTP binding to mycobacterial dUTPase is determined to be 10-fold less than for human dUTPase, which is to be considered in drug optimization. A robust continuous activity assay for kinetic screening is proposed.     

A thiamin-bound, pre-decarboxylation reaction intermediate analogue in the pyruvate dehydrogenase E1 subunit induces large scale disorder-to-order transformations in the enzyme and reveals novel structural features in the covalently bound adduct

The crystal structure of the E1 component from the Escherichia coli pyruvate dehydrogenase multienzyme complex (PDHc) has been determined with phosphonolactylthiamin diphosphate (PLThDP) in its active site. PLThDP serves as a structural and electrostatic analogue of the natural intermediate alpha-lactylthiamin diphosphate (LThDP), in which the carboxylate from the natural substrate pyruvate is replaced by a phosphonate group. This represents the first example of an experimentally determined, three-dimensional structure of a thiamin diphosphate (ThDP)-dependent enzyme containing a covalently bound, pre-decarboxylation reaction intermediate analogue and should serve as a model for the corresponding intermediates in other ThDP-dependent decarboxylases. Regarding the PDHc-specific reaction, the presence of PLThDP induces large scale conformational changes in the enzyme. In conjunction with the E1-PLThDP and E1-ThDP structures, analysis of a H407A E1-PLThDP variant structure shows that an interaction between His-407 and PLThDP is essential for stabilization of two loop regions in the active site that are otherwise disordered in the absence of intermediate analogue. This ordering completes formation of the active site and creates a new ordered surface likely involved in interactions with the lipoyl domains of E2s within the PDHc complex. The tetrahedral intermediate analogue is tightly held in the active site through direct hydrogen bonds to residues His-407, Tyr-599, and His-640 and reveals a new, enzyme-induced, strain-related feature that appears to aid in the decarboxylation process. This feature is almost certainly present in all ThDP-dependent decarboxylases; thus its inclusion in our understanding of general thiamin catalysis is important.     

dcd (dCTP deaminase) gene of Escherichia coli: mapping, cloning, sequencing, and identification as a locus of suppressors of lethal dut (dUTPase) mutations.

In Escherichia coli, most of the dUMP that is used as a substrate for thymidylate synthetase is generated from dCTP through the sequential action of dCTP deaminase and dUTPase. Some mutations of the dut (dUTPase) gene are lethal even when the cells are grown in the presence of thymidine, but their lethality can be suppressed by extragenic mutations that can be produced by transposon insertion. Six suppressor mutations were tested, and all were found to belong to the same complementation group. The affected gene was cloned, it was mapped by hybridization with a library of recombinant DNA, and its nucleotide sequence was determined. The gene is at 2,149 kb on the physical map. Its product, a 21.2-kDa polypeptide, was overproduced 1,000-fold via an expression vector and identified as dCTP deaminase, the enzyme affected in previously described dcd mutants. Null mutations in dcd probably suppress the lethality of dut mutations by reducing the accumulation of dUTP, which would otherwise lead to the excessive incorporation of uracil into DNA.     

Mechanistic studies of dUTPases

The essential enzyme dUTPase is responsible for preventive DNA repair via exclusion of uracil. Lack or inhibition of the enzyme induces thymine-less cell death in cells performing active DNA synthesis, serving therefore as an important chemotherapeutic target. In the present work, employing differential circular dichroism spectroscopy, we show that D. mel. dUTPase, a recently described eukaryotic model, has a similar affinity of binding towards alpha,beta-imino-dUTP as compared to the prokaryotic E. coli enzyme. However, in contrast to the prokaryotic dUTPase, the nucleotide exerts significant protection against tryptic digestion at a specific tryptic site 20 A far from the active site in the fly enzyme. This result indicates that binding of the nucleotide in the active site induces an allosteric conformational change within the central threefold channel of the homotrimer exclusively in the eukaryotic enzyme. Nucleotide binding induced allosterism in the D. mel. dUTPase, but not in the E. coli enzyme, might be associated with the altered hydropathy of subunit interfaces in these two proteins.     

Characteristics of a bacteriophage T4-induced complex synthesizing deoxyribonucleotides

A preparation of bacteriophage T4-induced deoxyribonucleotide synthetase complex is described. This very large complex of enzymes can be separated by centrifugation at 100,000 X g, by sucrose step gradient centrifugation, or with molecular exclusion columns. By direct assay and by unidimensional and two-dimensional acrylamide electrophoretic separations the following T4-coded enzymes were shown to be associated with the complex: ribonucleoside diphosphate reductase, dCMP deaminase, dCTP/dUTPase, dCMP hydroxymethylase, dTMP synthetase, and DNA polymerase. Other phage-coded prereplicative proteins related to DNA replication and other phage functions such as the proteins coded by genes 32, 46, rIIA, and rIIB as well as many unidentified proteins were also consistently associated with the isolated fractions. T4 DNA topoisomerase, a membrane-bound enzyme, was found in quantity in all purified fractions of the complex, even in preparations apparently free of membrane and of T4 DNA. The functional integrity of a segment of the complex was followed by measuring the conversion of [5-3H]CDP to the level of 5-hydroxymethyl dCMP. This series of reactions requires the actions of T4-coded ribonucleoside diphosphate reductase and its associated reducing system, dCTP/dUTPase and dCMP hydroxymethylase, 3H being lost to water at the last step. In this reaction sequence an intermediate, [5-3H]dCMP, is maintained at low steady state concentrations, and argument is presented that the synthesis of deoxyribonucleotides is channeled and normally tightly coupled to DNA replication. One of the primary characteristics of this complex is its ready dissociation of dilution into smaller complexes of proteins and to the free forms of the proteins. That the complex is held together by weak electrostatic forces was supported by its sensitivity to dissociation at moderate salt concentrations. Not only the enzymes required in deoxyribonucleotide synthesis but T4 DNA polymerase, T4 DNA topoisomerase, and a number of other proteins dissociate to varying degrees from the larger complexes under these conditions.     

A T4-phage deoxycytidylate deaminase mutant that no longer requires deoxycytidine 5'-triphosphate for activation

A deoxycytidylate (dCMP) deaminase encoded in T4-bacteriophage DNA that is induced on phage infection of Escherichia coli was shown earlier (Maley, G. F., Duceman, B. W., Wang, A. M., Martinez, J. M., and Maley, F. (1990) J. Biol. Chem. 265, 47-51) to be similar in size, properties, and amino acid composition to the T2-phage-induced deaminase. Neither enzyme is active in the absence of dCTP or its natural activator, 5-hydroxymethyl-dCTP. However, on changing the arginine (Arg) at residue 115 of the T4-deaminase to either a glutamate (R115E) or a glutamine (R115Q), the resulting mutant enzymes were active in the absence of dCTP, with each mutant possessing a turnover number or k(cat) that is about 15% that of the wild-type deaminase. When compared on the basis of specific activity, however, the mutants are about 40-50% of the wild-type (WT)-enzyme's specific activity. Molecular weight analysis on the wild-type and mutant deaminases using HPLC size exclusion chromatography revealed that the wild-type deaminase was basically a hexamer, particularly in the presence of dCTP, regardless of the extent of dilution. Under similar conditions, R115E remained a dimer, whereas R115Q and F112A varied from hexamers to dimers particularly at concentrations normally present in the assay solution. Activity measurements appear to support the conclusion that the hexameric form of the enzyme is activated by dCTP, while the dimer is not. Another feature emphasizing the difference between the WT and mutant deaminases was observed on their denaturation-renaturation in EDTA, which revealed the mutants to be restored to 50% of their original activities with the WT deaminase only marginally restored.     

Chloroviruses encode a bifunctional dCMP-dCTP deaminase that produces two key intermediates in dTTP formation

The chlorovirus PBCV-1, like many large double-stranded DNA-containing viruses, contains several genes that encode putative proteins involved in nucleotide biosynthesis. This report describes the characterization of the PBCV-1 dCMP deaminase, which produces dUMP, a key intermediate in the synthesis of dTTP. As predicted, the recombinant protein has dCMP deaminase activity that is activated by dCTP and inhibited by dTTP. Unexpectedly, however, the viral enzyme also has dCTP deaminase activity, producing dUTP. Typically, these two reactions are catalyzed by proteins in separate enzyme classes; to our knowledge, this is the first example of a protein having both deaminase activities. Kinetic experiments established that (i) the PBCV-1 enzyme has a higher affinity for dCTP than for dCMP, (ii) dCTP serves as a positive heterotropic effector for the dCMP deaminase activity and a positive homotropic effector for the dCTP deaminase activity, and (iii) the enzymatic efficiency of the dCMP deaminase activity is about four times higher than that of the dCTP deaminase activity. Inhibitor studies suggest that the same active site is involved in both dCMP and dCTP deaminations. The discovery that the PBCV-1 dCMP deaminase has two activities, together with a previous report that the virus also encodes a functional dUTP triphosphatase (Y. Zhang, H. Moriyama, K. Homma, and J. L. Van Etten, J. Virol. 79:9945-9953, 2005), means that PBCV-1 is the first virus to encode enzymes involved in all three known pathways to form dUMP.     

Mechanistic Studies of dUTPases

The essential enzyme dUTPase is responsible for preventive DNA repair via exclusion of uracil. Lack or inhibition of the enzyme induces thymine‐less cell death in cells performing active DNA synthesis, serving therefore as an important chemotherapeutic target. In the present work, employing differential circular dichroism spectroscopy, we show that D. mel. dUTPase, a recently described eukaryotic model, has a similar affinity of binding towards α,β‐imino‐dUTP as compared to the prokaryotic E. coli enzyme. However, in contrast to the prokaryotic dUTPase, the nucleotide exerts significant protection against tryptic digestion at a specific tryptic site 20 Å far from the active site in the fly enzyme. This result indicates that binding of the nucleotide in the active site induces an allosteric conformational change within the central threefold channel of the homotrimer exclusively in the eukaryotic enzyme. Nucleotide binding induced allosterism in the D. mel. dUTPase, but not in the E. coli enzyme, might be associated with the altered hydropathy of subunit interfaces in these two proteins.     

Catalytic mechanism of α-phosphate attack in dUTPase is revealed by X-ray crystallographic snapshots of distinct intermediates, 31P-NMR spectroscopy and reaction path modelling

Enzymatic synthesis and hydrolysis of nucleoside phosphate compounds play a key role in various biological pathways, like signal transduction, DNA synthesis and metabolism. Although these processes have been studied extensively, numerous key issues regarding the chemical pathway and atomic movements remain open for many enzymatic reactions. Here, using the Mason–Pfizer monkey retrovirus dUTPase, we study the dUTPase-catalyzed hydrolysis of dUTP, an incorrect DNA building block, to elaborate the mechanistic details at high resolution. Combining mass spectrometry analysis of the dUTPase-catalyzed reaction carried out in and quantum mechanics/molecular mechanics (QM/MM) simulation, we show that the nucleophilic attack occurs at the α-phosphate site. Phosphorus-31 NMR spectroscopy (³¹P-NMR) analysis confirms the site of attack and shows the capability of dUTPase to cleave the dUTP analogue α,β-imido-dUTP, containing the imido linkage usually regarded to be non-hydrolyzable. We present numerous X-ray crystal structures of distinct dUTPase and nucleoside phosphate complexes, which report on the progress of the chemical reaction along the reaction coordinate. The presently used combination of diverse structural methods reveals details of the nucleophilic attack and identifies a novel enzyme–product complex structure.     

Evaluation of cysteine 283 and glutamic acid 284 in the coenzyme binding site of Salmonella typhimurium glutamate dehydrogenase by site-directed mutagenesis and reaction with the nucleotide analogue 2-[4-bromo-2,3-dioxobutyl)thio)-1,N6-ethenoadenosine 2',5'-bisphosphate.

NADP(+)-specific glutamate dehydrogenase of Salmonella typhimurium was previously shown to react irreversibly at the coenzyme site with the nucleotide analogue 2-((4-bromo-2,3-dioxobutyl)thio)-1,N6-ethenoadenosine 2',5'-bisphosphate (2-BDB-T epsilon A 2',5'-DP) yielding a partially active enzyme, and inactivation was attributed to modification of the peptide Leu282-Cys-Glu-Ile-Lys286 (Bansal, A., Dayton, M.A., Zalkin, H., and Colman, R.F. (1989) J. Biol. Chem. 264, 9827-9835). Three mutant enzymes have now been engineered, expressed in Escherichia coli, and purified: the single mutants C283I and E284Q and the double mutant C283I:E284Q. The wild-type and mutant enzymes have similar specific activities and Km values for alpha-ketoglutarate, ammonium ion, and NADPH, indicating that neither cysteine 283 nor glutamic acid 284 is essential for activity. The mutant enzyme E284Q, like wild-type glutamate dehydrogenase, is substantially inactivated by 2-BDB-T epsilon A 2',5'-DP. In contrast, the two cysteine mutant enzymes, C283I and C283I:E284Q, are not inactivated by 2-BDB-T epsilon A 2',5'-DP. Modified tryptic peptides with the sequence Leu-X-Glu(Gln)-Ile-Lys were isolated from wild-type or E284Q enzymes inactivated by 2-BDB-T epsilon A 2',5'-DP. This peptide was absent from digests of active wild-type enzyme modified in the presence of the protectant NADPH and from digests of active C283I enzyme after incubation with 2-BDB-T epsilon A 2',5'-DP. Although it is not required for catalytic activity, cysteine 283 is implicated by the results of the affinity labeling experiments as the reaction target of the nucleotide analogue and is located in the region of the coenzyme binding site.     

Crystal structures of Streptococcus mutans 2'-deoxycytidylate deaminase and its complex with substrate analog and allosteric regulator dCTP x Mg2+

2′-Deoxycytidylate deaminase [or deoxycytidine-5′-monophosphate (dCMP) deaminase, dCD] catalyzes the deamination of dCMP to deoxyuridine-5′-monophosphate to provide the main nucleotide substrate for thymidylate synthase, which is important in DNA synthesis. The activity of this homohexameric enzyme is allosterically regulated by deoxycytidine-5′-triphosphate (dCTP) as an activator and by deoxythymidine-5′-triphosphate as an inhibitor. In this article, we report the crystal structures of dCMP deaminase from Streptococcus mutans and its complex with dCTP and an intermediate analog at resolutions of 3.0 and 1.66 Å. The protein forms a hexamer composed of subunits adopting a three-layer α/β/α sandwich fold. The positive allosteric regulator dCTP mainly binds at the interface between two monomers in a molar ratio of 1:1 and rearranges the neighboring interaction networks. Structural comparisons and sequence alignments revealed that dCMP deaminase from Streptococcus mutans belongs to the cytidine deaminase superfamily, wherein the proteins exhibit a similar catalytic mechanism. In addition to the two conserved motifs involved in the binding of Zn^2 +, a new conserved motif, (G⁴³YNG⁴⁶), related to the binding of dCTP was also identified. N-terminal Arg4, a key residue located between two monomers, binds strongly to the γ phosphate group of dCTP. The regulation signal was transmitted by Arg4 from the allosteric site to the active site via modifications in the interactions at the interface where the substrate-binding pocket was involved and the relocations of Arg26, His65, Tyr120, and Arg121 to envelope the active site in order to stabilize substrate binding in the complex. Based on the enzyme-regulator complex structure observed in this study, we propose an allosteric mechanism for dCD regulation.