Transient kinetics of ligand binding and role of the C-terminus in the dUTPase from equine infectious anemia virus.

Transient kinetics of the equine infectious anemia virus deoxyuridine 5'-triphosphate nucleotide hydrolase were characterized by monitoring the fluorescence of the protein. Rate constants for the association and dissociation of substrate and inhibitors were determined and found to be consistent with a one-step mechanism for substrate binding. A C-terminal part of the enzyme presumed to be flexible was removed by limited trypsinolysis. As a result, the activity of the dUTPase was completely quenched, but the rate constants and fluorescent signal of the truncated enzyme were affected only to a minor degree. We conclude that the flexible C-terminus is not a prerequisite for substrate binding, but indispensable for catalysis.

Crystal structure of dUTPase from equine infectious anaemia virus; active site metal binding in a substrate analogue complex.

The X-ray structures of dUTPase from equine infectious anaemia virus (EIAV) in unliganded and complexed forms have been determined to 1.9 and 2.0 A resolution, respectively. The structures were solved by molecular replacement using Escherichia coli dUTPase as search model. The exploitation of a relatively novel refinement approach for the initial model, combining maximum likelihood refinement with stereochemically unrestrained updating of the model, proved to be of crucial importance and should be of general relevance.EIAV dUTPase is a homotrimer where each subunit folds into a twisted antiparallel beta-barrel with the N and C-terminal portions interacting with adjacent subunits. The C-terminal 14 and 17 amino acid residues are disordered in the crystal structure of the unliganded and complexed enzyme, respectively. Interactions along the 3-fold axis include a water-containing volume (size 207 A3) which has no contact with bulk solvent. It has earlier been shown that a divalent metal ion is essential for catalysis. For the first time, a putative binding site for such a metal ion, in this case Sr2+, is established. The positions of the inhibitor (the non-hydrolysable substrate analogue dUDP) and the metal ion in the complex are consistent with the location of the active centre established for trimeric dUTPase structures, in which subunit interfaces form three surface clefts lined with evolutionary conserved residues. However, a detailed comparison of the active sites of the EIAV and E. coli enzymes reveals some structural differences. The viral enzyme undergoes a small conformational change in the uracil-binding beta-hairpin structure upon dUDP binding not observed in the other known dUTPase structures.

The refined structure of dUTPase from Escherichia coli.

Deoxyuridine 5'-triphosphate nucleotidohydrolase (dUTPase, E.C. 3.6. 1.23) catalyzes the hydrolysis of dUTP to dUMP and pyrophosphate and is involved in nucleotide metabolism and DNA synthesis. A crystal of the recombinant E. coli enzyme, precipitated from polyethylene glycol mixtures in the presence of succinate at pH 4.2, was used to collect synchrotron diffraction data to 1.9 A resolution, in space group R3, a = b = 86.62, c = 62.23 A. Mercury and platinum derivative data were collected at wavelengths to optimize the anomalous contribution. The resulting 2.2 A MIRAS phases differed from the final set by 40 degrees on average and produced an excellent map which was easy to interpret. The model contains 132 water molecules and refined to an R value of 13.7%. 136 residues have clear electron density out of 152 expected from the gene sequence. The 16 C-terminal residues are presumably disordered in the crystal lattice. The monomer is a 'jelly-roll' type, containing mostly beta-sheet and only one short helix. The molecule is a tight trimer. A long C-terminal arm extends from one subunit and encompasses the next one within the trimer contributing to its beta-sheet. Conserved sequence motifs common among dUTPases, previously suggested to compose the active site and confirmed in a recent study of the dUDP complex, are located at subunit-subunit interfaces along the threefold axis, in parts of the beta-sheet and in loop regions. A similar molecular architecture has recently been found in two other trimeric dUTPases.

The complete triphosphate moiety of non-hydrolyzable substrate analogues is required for a conformational shift of the flexible C-terminus in E. coli dUTP pyrophosphatase.

The molecular mechanism of substrate analogue interaction with Escherichia coli dUTPase was investigated, using the non-hydrolyzable 2'-deoxyuridine 5'-(alpha,beta-imido)triphosphate (alpha,beta-imido-dUTP). Binding of this analogue induces a difference in the far UV circular dichroism (CD) spectrum arguing for a significant change in protein conformation. The spectral shift is strictly Mg2+-dependent, does not appear with dUDP instead of alpha,beta-imido-dUTP and is not elicited if the flexible C-terminal arm is deleted from the protein by limited tryptic digestion. Involvement of the C-terminal arm in alpha,beta-imido-dUTP binding is consistent with the finding that this analogue protects against tryptic hydrolysis at Arg-141. Near UV CD of ligand-enzyme complexes reveals a characteristic difference in the microenvironments of enzyme-bound dUDP and alpha,beta-imido-dUTP, a difference not observable in C-terminally truncated dUTPase. The results suggest that (i) closing of the active site during the catalytic cycle, through the movement of the C-terminal arm, requires the presence of the complete triphosphate moiety of the substrate in complex with Mg2+, and (ii) after catalytic cleavage the active site pops open to facilitate product release.

Kinetic properties and stereospecificity of the monomeric dUTPase from herpes simplex virus type 1.

Kinetic properties of the monomeric enzyme dUTPase from herpes simplex virus type 1 (HSV) were investigated and compared to those previously determined for homotrimeric dUTPases of bacterial and retroviral origins. The HSV and Escherichia coli dUTPases are equally potent as catalysts towards the native substrate dUTP with a kcat/K(M) of about 10(7) M(-1) s(-1) and a K(M) of 0.3 microM. However, the viral enzymes are less specific than the bacterial enzyme. The HSV and E. coli dUTPases show the same stereospecificity towards the racemic substrate analogue dUTPalphaS (2'-deoxyuridine 5'-(alpha-thio)triphosphate), suggesting that they have identical reaction mechanisms.

dUTPase from the retrovirus equine infectious anemia virus: specificity, turnover and inhibition.

The kinetic properties of dUTPase from equine infectious anemia virus (EIAV) were investigated. K(M) (1.1 +/- 0.1 microM) and k(cat) (25 s(-1)) were found to be independent of pH in the neutral pH range. Above pH 8.0, K(M) increases slightly. Below pH 6.0, the enzyme is rapidly deactivated. Detergent was found to enhance activity, leaving K(M) and k(cat) unaffected. Compared to the Escherichia coli dUTPase, the EIAV enzyme is equally potent in hydrolyzing dUTP, but less specific. Inhibition of the viral enzyme by the nucleotides dTTP, dUMP and a synthetic analogue, 2'-deoxyuridine 5'-(alpha,beta-imido)triphosphate, is stronger by one order of magnitude.

The dUTPases from herpes simplex virus type 1 and mouse mammary tumour virus are less specific than the Escherichia coli enzyme.

The enzyme dUTPase catalyses the hydrolysis of dUTP to dUMP and pyrophosphate, thereby suppressing incorporation of uracil into DNA and providing a pool of dUMP, the precursor of dTTP. Hydrolysis of other nucleotides similar in structure to dUTP would conceivably be physiologically detrimental and high specificity of the reaction seems to be necessary. In this work, we characterize the substrate specificity of the dUTPases from herpes simplex virus type 1 (HSV-1) and mouse mammary tumour virus (MMTV) in comparison to the Escherichia coli enzyme. We tested dCTP, dTTP, UTP and dUDP as substrates. Significantly higher reactivity was observed for the HSV-1 enzyme with dCTP and dTTP and for the MMTV enzyme with dTTP and UTP. The lower substrate specificity of the two virus enzymes compared with the bacterial enzyme is discussed in relation to the DNA precursor metabolism during virus replication.

Crystallization and preliminary X-ray analysis of human dUTPase.

Human dUTPase, expressed in Escherichia coli, has been crystallized. Single crystals were obtained by the vapour-diffusion technique using 2-propanol and PEG 4000 as precipitants. The enzyme was co-crystallized with the substrate dUTP and a metal chelator EDTA to prevent hydrolysis of the substrate. The crystals belong to the orthorombic space group P2(1)2(1)2(1) with cell dimensions a = 67.51, b = 68.26 and c = 91.00 A. The crystallographic asymmetric unit contains one trimer of identical subunits.

Kinetic characterization of dUTPase from Escherichia coli.

The enzyme dUTPase catalyzes the hydrolysis of dUTP to dUMP and pyrophosphate, thereby preventing a deleterious incorporation of uracil into DNA. The best known dUTPase is that from Escherichia coli, which, like the human enzyme, consists of three identical subunits. In the present work, the catalytic properties of the E. coli dUTPase were investigated in the pH range 5-11. The enzyme was found to be highly specific for dUTP and discriminated both base and sugar as well as the phosphate moiety (bound dUDP was not hydrolyzed). The second best substrate among the nucleotides serving as building blocks for DNA was dCTP, which was hydrolyzed an astonishing 10(5) times less efficiently than dUTP, a decline largely accounted for by a higher Km for dCTP. With dUTP.Mg as substrate, kcat was found to vary little with pH and to range from 6 to 9 s-1. Km passed through a broad minimum in the neutral pH range with values approaching 10(-7) M. It increased with deprotonation of the uracil moiety of dUTP and showed dependence on two ionizations in the enzyme, exhibiting pKa values of 5.8 and 10.3. When excess dUTPase was reacted with dUTP middle dotMg at pH 8, the two protons transferred to the reaction medium were released in a concerted mode after the rate-limiting step. The Mg2+ ion enhances binding to dUTPase of dUTP by a factor of 100 and dUDP by a factor of 10. Only one enantiomer of the substrate analog 2'-deoxyuridine-5'-(alpha-thio)-triphosphate was hydrolyzed by the enzyme. These results are interpreted to favor a catalytic mechanism involving magnesium binding to the alpha-phosphate, rate-limiting hydrolysis by a shielded and activated water molecule and a fast ordered desorption of the products. The results are discussed with reference to recent data on the structure of the E. coli dUTPase.UDP complex.

Crystal structure of the Escherichia coli dUTPase in complex with a substrate analogue (dUDP).

We have determined the structure of the homotrimeric dUTPase from Escherichia coli, completed with an inhibitor and substrate analogue, dUDP. Three molecules of dUDP are found symmetrically bound per trimer, each in a shallow cleft between adjacent subunits, interacting with evolutionary conserved residues. The interactions of the uracil ring and the deoxypentose with the protein are consistent with the high specificity of the enzyme with respect to these groups. The positions of the two phosphate groups and adjacent water molecules are discussed in relation to the mechanism and kinetics of catalysis. The role that dUTPase plays in DNA metabolism makes the enzyme a potential target for chemotherapeutic drugs: the results presented here will aid in the design and development of inhibitory compounds.

A cluster of genes encoding major isozymes of lignin peroxidase and manganese peroxidase from the white-rot fungus Trametes versicolor.

A gene cluster from the white-rot basidiomycete Trametes (Coriolus) versicolor (Tv) PRL 572 containing three structural genes, LPGIII, LPGIV and MPGI, was characterized. The genes are arranged in the same transcriptional direction, within a 10-kb region, and found to encode quantitatively dominant isozymes of lignin peroxidase (LP) and manganese peroxidase (MP). The second gene in sequence, LPGIV, predicts a 346-amino-acid (aa) mature polypeptide (36.9 kDa, pI 4.31) which is identical with the partial aa sequence information available on the LP12 isozyme (43.1 kDa, pI 3.27). The first gene, LPGIII, encodes a 341-aa polypeptide (36.1 kDa, pI 3.93) which has not been identified at the protein level. However, the similarity of LPGIV would suggest that the predicted product is an LP-type enzyme. LPGIII and LPGIV are homologous to the tandemly arranged genes LPGII and LPGI, respectively, recently described by Jönsson and Nyman [Biochim. Biophys. Acta 1218 (1994) 408-412]. The homologous genes, LPGIII/LPGII and LPGIV/LPGI, are 99% and 96% identical in sequence, respectively, and are predicted to encode identical polypeptides, since base substitutions in the predicted exons are all synonymous. The third gene, MPGI, is different in intron-exon organization and predicted to be disrupted by five rather than six introns, as are the LP genes. The deduced polypeptide, 339 aa in size (35.9 kDa, pI 4.07), is identical with the partial aa sequence information available for isozyme MP2 (44.5 kDa, pI 3.09). The MPGI- and LPGIV-encoded polypeptides are 70% identical in sequence which suggests that MP and LP from Tv may be regarded as members of the same family within the plant peroxidase superfamily. Most importantly, this study identifies a gene encoding the MP2 isozyme, and further shows that genes encoding MP and LP can be closely linked on the chromosome and may be coordinately transcribed.

Synthesis of 2'-deoxyuridine 5'-(alpha,beta-imido) triphosphate: a substrate analogue and potent inhibitor of dUTPase.

The dUDP analogue, 2'-deoxyuridine 5'-(alpha,beta-imido)diphosphate (dUPNP) was synthesized. The corresponding triphosphate analogue (dUPNPP) was prepared by enzymic phosphorylation of dUPNP using the enzyme pyruvate kinase and phosphoenolpyruvate as the phosphate donor. This method was successful in phosphorylating the imidodiphosphate analogue of 2'-deoxythymidine (dTPNP) to 2'-deoxythymidine 5'-(alpha, beta-imido)triphosphate (dTPNPP), in contradiction to a previous report. The properties of dUPNPP have been tested using the enzyme dUTPase from Escherichia coli. This enzyme, having a crucial role in nucleotide metabolism, is strictly specific for its substrate (dUTP) and catalyzes the hydrolysis of the alpha, beta-bridge, resulting in dUMP and pyrophosphate. Replacement of the alpha, beta-bridging oxygen in dUTP with an imido group resulted in a nonhydrolyzable substrate analogue and a potent competitive inhibitor of dUTPase (Ki = 5 microM). The analogue prepared (dUPNPP) may be utilized in crystallographic studies of the active site of dUTPase to provide knowledge about specific interactions involved in substrate binding and as a parental compound in design of dUTPase inhibition for medical purposes.

Specific derivatization of the active site tyrosine in dUTPase perturbs ligand binding to the active site.

Selective modification of one (of three) tyrosine residue per enzyme monomer leads to inactivation of dUTPase of the retrovirus equine infectious anemia virus (EIAV). The substrate dUMP and the cofactor Mg2+ protect against inactivation and modification, in agreement with the study on E. coli dUTPase (Vertessy et al. (1994) Biochim. Biophys. Acta 1205, 146-150). Amino acid analyses of nitrated dUTPases confirmed Tyr-selectivity of modification. The nitrated residue in E. coli dUTPase was identified as the evolutionary highly conserved Tyr-93. The modifiable residue is shown to be the only Tyr exposed in both E. coli and EIAV dUTPases. As a consequence of Tyr-93 derivatization, the Mg2+-dependent interaction between the substrate-analogue dUDP and E. coli dUTPase becomes impaired as shown by circular dichroism spectroscopy, here presented as a tool for monitoring ligand binding to the active site.

Characterization of a laccase gene from the white-rot fungus Trametes versicolor and structural features of basidiomycete laccases.

A gene coding for the multi-copper phenol oxidase laccase has been isolated from the white-rot basidiomycete Trametes versicolor. The gene, which is preceded by a TATA box and a pyrimidine-rich region, is predicted to contain ten introns. The mature translation product, preceded by a 22-residue signal peptide, should consist of 498 residues. Comparisons with Edman degradation data of peptides from T. versicolor laccase strongly suggest that two disulfide bridges are formed by Cys-85/Cys-487 and Cys-117/Cys-205, respectively. The encoded protein contains five Cys, and the sequence surrounding the remaining Cys-452 is consistent with its involvement in the ligation of type-1 copper. Alignment of sequences indicates that T. versicolor laccase displays a Phe at the position corresponding to a residue (Met in ascorbate oxidase and azurin) considered important for the reduction potential of type-1 copper proteins.

The gene from the white-rot fungus Trametes versicolor encoding the lignin peroxidase isozyme LP7.

The structural gene LPGVI (1463 bp including 6 introns), characterized from the white-rot basidiomycete Trametes versicolor (PRL 572), encodes a 342-residue mature polypeptide of 36.7 kDa, preceded by a 26-residue signal/propeptide. LPGVI is identified as the gene encoding the 43 kDa lignin peroxidase isozyme LP7 as based on the partial amino acid sequence information available. The polypeptide deduced shares 72-74% identity in sequence with other lignin peroxidases and 70% with a manganese (II) peroxidase from T. versicolor.

dUTPase from the retrovirus equine infectious anemia virus: high-level expression in Escherichia coli and purification.

Deoxyuridine 5'-triphosphate nucleotidohydrolase (dUTPase, EC 3.6.1.23) catalyzes the hydrolysis of dUTP to dUMP and pyrophosphate, and plays important roles in nucleotide metabolism and DNA replication. The dUTPase gene of the retrovirus equine infectious anemia virus (EIAV) was cloned and overexpressed in Escherichia coli using the T7 RNA polymerase expression system. The recombinant vector (pET-3a/EDU), constructed by mutagenic PCR, was transformed into E. coli BL21 (DE3) pLysS cells, resulting in expression of EIAV dUTPase at about 40% of the extracted protein. This level of overproduction is very high compared to previous reports on heterologous expression of dUTPases in E. coli. A one-step purification procedure using phosphocellulose chromatography results in a homogeneous preparation of the enzyme in a yield of 45 mg liter-1 of bacterial culture. The purified EIAV dUTPase, run on a sodium dodecyl sulfate-polyacrylamide gel electrophoresis, shows an apparent molecular mass of 15.1 kDa in accordance with the gene structure. The isoelectric point (pI) was determined to 5.6. Gel filtration under nondenaturating conditions gives a retention volume corresponding to a molecular mass of 40.6 kDa, suggesting a trimeric organization of the enzyme. The amino acid composition and amino-terminal sequence of the recombinant dUTPase are in agreement with predictions from the DNA sequence.

The protein p30, encoded at the gag-pro junction of mouse mammary tumor virus, is a dUTPase fused with a nucleocapsid protein.

A ribosomal frameshift at the gag-pro junction of mouse mammary tumor virus (MMTV) gives rise to the protein p30. The protein consists of two domains, the zinc-finger-containing nucleocapsid (NC) protein portion with 95 residues and a C-terminal extension comprising 154 residues. The C-terminal domain shows similarity in sequence with the enzyme dUTPase from other sources. In this paper, we demonstrate that p30 is a functional dUTPase. Overproduction of the NC protein in Escherichia coli, using the native frameshift sequence at the gag stop codon, caused a detectable expression of dUTPase ascribed to a low frequency of readthrough. By a 1-base insertion, eliminating the gag stop codon and fusing the gag and pro reading frames, a plasmid, pET-3d-NCDU, directing overexpression of p30, was constructed. The overproduced protein, purified by phosphocellulose chromatography, shows both zinc-binding and dUTPase activity. Analytical gel filtration and sequence homology to other dUTPases suggest a trimeric assembly of p30 subunits. MMTV thus possesses two different forms of the nucleocapsid protein, the ordinary NC protein and the p30, having the NC protein connected to a domain of dUTPase.

Tandem lignin peroxidase genes of the fungus Trametes versicolor.

A DNA fragment containing two lignin peroxidase genes (LPG I and LPG II) has been isolated from a genomic library of the white-rot fungus Trametes versicolor. The genes are separated by 2.2 kbp and have the same direction of transcription. Conserved elements preceding the translation start have been identified. In addition to the TATA box, a stretch of 11 identical nucleotides is found 23-24 bp downstream of the TATA box. The putative mature peroxidases encoded by LPG I and LPG II are 87% identical in amino acid sequence. Both are preceded by two basic residues, also observed in lignin peroxidases from Phanerochaete chrysosporium. Strong evidence suggests that LPG I encodes a quantitatively dominant lignin peroxidase isozyme (TvLP12), whereas the product of LPF II has not been identified so far.

A novel type of peroxidase gene from the white-rot fungus Trametes versicolor.

The wood-decaying fungus Trametes versicolor secretes a large number of peroxidase isozymes, presumed to partake in the degradation of lignin. From enzymic studies, two types of peroxidases have been distinguished: lignin peroxidases and manganese peroxidases. We here report the finding of a T. versicolor peroxidase gene, PG V, which displays several features not observed in previously studied peroxidase genes from white-rot fungi, such as a high number of introns (12). Eight of the 12 introns have positions equivalent to introns of peroxidase genes from another white-rot fungus, Phanerochaete chrysosporium. The gene structure of PG V appears to be primarily related to known lignin peroxidase genes, while the encoded mature 339-residue protein has several characteristics in common with manganese peroxidases. Analyses further indicate that PG V encodes a Ser instead of an Asn at a position regarded as invariant within the enzyme superfamily, with the side chain involved in hydrogen bonding with the distal His.