A unique catalytic and inhibitor-binding role for Lys93 of yeast orotidylate decarboxylase

Orotidine Monophosphate Decarboxylase--A Fascinating Workhorse Enzyme with Therapeutic Potential

Orotidine 5'-monophosphate decarboxylase (ODCase) is known as one of the most proficient enzymes. The enzyme catalyzes the last reaction step of the de novo pyrimidine biosynthesis, the conversion from orotidine 5'-monophosphate (OMP) to uridine 5'-monophosphate. The enzyme is found in all three domains of life, Bacteria, Eukarya and Archaea. Multiple sequence alignment of 750 putative ODCase sequences resulted in five distinct groups. While the universally conserved DxKxxDx motif is present in all the groups, depending on the groups, several characteristic motifs and residues can be identified. Over 200 crystal structures of ODCases have been determined so far. The structures, together with biochemical assays and computational studies, elucidated that ODCase utilized both transition state stabilization and substrate distortion to accelerate the decarboxylation of its natural substrate. Stabilization of the vinyl anion intermediate by a conserved lysine residue at the catalytic site is considered the largest contributing factor to catalysis, while bending of the carboxyl group from the plane of the aromatic pyrimidine ring of OMP accounts for substrate distortion. A number of crystal structures of ODCases complexed with potential drug candidate molecules have also been determined, including with 6-iodo-uridine, a potential antimalarial agent.

Quantum and classical simulations of orotidine monophosphate decarboxylase: support for a direct decarboxylation mechanism

Orotidine 5'-monophosphate (OMP) decarboxylase (ODCase) catalyzes the decarboxylation of OMP to uridine 5'-monophosphate (UMP). Numerous studies of this reaction have suggested a plethora of mechanisms including covalent addition, ylide or carbene formation, and concerted or stepwise protonation. Recent experiments and simulations present strong evidence for a direct decarboxylation mechanism, although direct comparison between experiment and theory is still lacking. In the current work we present hybrid quantum mechanics-molecular mechanics simulations that address the detailed decarboxylation mechanisms for OMP and 5-fluoro-OMP by ODCase. Multidimensional potentials of mean force are computed as functions of structural progress coordinates for the Methanobacterium thermoautotrophicum ODCase reaction: the decarboxylation reaction coordinate, an orbital rehybridization coordinate, and the proton transfer coordinate between Lys72 and the substrate. The computed free energy profiles are in accord with the available experimental data. To facilitate further direct comparison with experiment, we compute the kinetic isotope effects (KIEs) for the enzyme-catalyzed reactions using a mass-perturbation-based path-integral method. The computed KIE provide further support for a direct decarboxylation mechanism. In agreement with experiment, the data suggest a role for Lys72 in stabilizing the transition state in the catalysis of OMP and, to a somewhat lesser extent, in 5-fluoro-OMP.

Chemical mutagenesis of vaccinia DNA topoisomerase lysine 167 provides insights to the catalysis of DNA transesterification

Vaccinia DNA topoisomerase IB (TopIB) relaxes supercoils by forming and resealing a covalent DNA-(3'-phosphotyrosyl(274))-enzyme intermediate. Conserved active site side chains promote the attack of Tyr274 on the scissile phosphodiester via transition state stabilization and general acid catalysis. Two essential side chains, Lys167 and Arg130, act in concert to protonate and expel the 5'-O leaving group. Here we gained new insights to catalysis through chemical mutagenesis of Lys167. Changing Lys167 to cysteine crippled the DNA cleavage and religation transesterification steps (k(cl) = 4.3 × 10(-4) s(-1); k(rel) = 9 × 10(-4) s(-1)). The transesterification activities of the K167C enzyme were revived by in vitro alkylation with 2-bromoethylamine (k(cl) = 0.031 s(-1); k(rel) ≥ 0.4 s(-1)) and 3-bromopropylamine (k(cl) = 0.013 s(-1); k(rel) = 0.22 s(-1)), which convert the cysteines to γ-thialysine and γ-thiahomolysine, respectively. These chemically installed lysine analogues were more effective than a genetically programmed arginine 167 substitution characterized previously. The modest differences in the transesterification rates of the 2-bromoethylamine- and 3-bromopropylamine-treated enzymes highlight that TopIB is tolerant of a longer homolysine side chain for assembly of the active site and formation of the transition state.

Proton transfer from C-6 of uridine 5'-monophosphate catalyzed by orotidine 5'-monophosphate decarboxylase: formation and stability of a vinyl carbanion intermediate and the effect of a 5-fluoro substituent

The exchange for deuterium of the C-6 protons of uridine 5'-monophosphate (UMP) and 5-fluorouridine 5'-monophosphate (F-UMP) catalyzed by yeast orotidine 5'-monophosphate decarboxylase (ScOMPDC) at pD 6.5-9.3 and 25 °C was monitored by (1)H NMR spectroscopy. Deuterium exchange proceeds by proton transfer from C-6 of the bound nucleotide to the deprotonated side chain of Lys-93 to give the enzyme-bound vinyl carbanion. The pD-rate profiles for k(cat) give turnover numbers for deuterium exchange into enzyme-bound UMP and F-UMP of 1.2 × 10(-5) and 0.041 s(-1), respectively, so that the 5-fluoro substituent results in a 3400-fold increase in the first-order rate constant for deuterium exchange. The binding of UMP and F-UMP to ScOMPDC results in 0.5 and 1.4 unit decreases, respectively, in the pK(a) of the side chain of the catalytic base Lys-93, showing that these nucleotides bind preferentially to the deprotonated enzyme. We also report the first carbon acid pK(a) values for proton transfer from C-6 of uridine (pK(CH) = 28.8) and 5-fluorouridine (pK(CH) = 25.1) in aqueous solution. The stabilizing effects of the 5-fluoro substituent on C-6 carbanion formation in solution (5 kcal/mol) and at ScOMPDC (6 kcal/mol) are similar. The binding of UMP and F-UMP to ScOMPDC results in a greater than 5 × 10(9)-fold increase in the equilibrium constant for proton transfer from C-6, so that ScOMPDC stabilizes the bound vinyl carbanions, relative to the bound nucleotides, by at least 13 kcal/mol. The pD-rate profile for k(cat)/K(m) for deuterium exchange into F-UMP gives the intrinsic second-order rate constant for exchange catalyzed by the deprotonated enzyme as 2300 M(-1) s(-1). This was used to calculate a total rate acceleration for ScOMPDC-catalyzed deuterium exchange of 3 × 10(10) M(-1), which corresponds to a transition-state stabilization for deuterium exchange of 14 kcal/mol. We conclude that a large portion of the total transition-state stabilization for the decarboxylation of orotidine 5'-monophosphate can be accounted for by stabilization of the enzyme-bound vinyl carbanion intermediate of the stepwise reaction.

Lys314 is a nucleophile in non-classical reactions of orotidine-5'-monophosphate decarboxylase

Orotidine-5'-monophosphate decarboxylase (OMPD) catalyzes the decarboxylation of orotidine-5'-monophosphate (OMP) to uridine-5'-monophosphate (UMP) in an extremely proficient manner. The reaction does not require any cofactors and proceeds by an unknown mechanism. In addition to decarboxylation, OMPD is able to catalyze other reactions. We show that several C6-substituted UMP derivatives undergo hydrolysis or substitution reactions that depend on a lysine residue (Lys314) in the OMPD active site. 6-Cyano-UMP is converted to UMP, and UMP derivatives with good leaving groups inhibit OMPD by a suicide mechanism in which Lys314 covalently binds to the substrate. These non-classical reactivities of human OMPD were characterized by cocrystallization and freeze-trapping experiments with wild-type OMPD and two active-site mutants by using substrate and inhibitor nucleotides. The structures show that the C6-substituents are not coplanar with the pyrimidine ring. The extent of this substrate distortion is a function of the substituent geometry. Structure-based mechanisms for the reaction of 6-substituted UMP derivatives are extracted in accordance with results from mutagenesis, mass spectrometry, and OMPD enzyme activity. The Lys314-based mechanisms explain the chemodiversity of OMPD, and offer a strategy to design mechanism-based inhibitors that could be used for antineoplastic purposes for example.

QM/MM metadynamics study of the direct decarboxylation mechanism for orotidine-5'-monophosphate decarboxylase using two different QM regions: acceleration too small to explain rate of enzyme catalysis

Despite decades of study, the mechanism by which orotidine-5'-monophosphate decarboxylase (ODCase) catalyzes the decarboxylation of orotidine monophosphate remains unresolved. A computational investigation of the direct decarboxylation mechanism has been performed using mixed quantum mechanical/molecular mechanical (QM/MM) dynamics simulations. The study was performed with the program CP2K that integrates classical dynamics and ab initio dynamics based on the Born-Oppenheimer approach. Two different QM regions were explored. The free energy barriers for direct decarboxylation of orotidine-5'-monophosphate (OMP) in solution and in the enzyme (using the larger QM region) were determined with the metadynamics method to be 40 and 33 kcal/mol, respectively. The calculated change in activation free energy (DeltaDeltaG++) on going from solution to the enzyme is therefore -7 kcal/mol, far less than the experimental change of -23 kcal/ mol (for k(cat.)/k(uncat.): Radzicka, A.; Wolfenden, R., Science 1995, 267, 90-92). These results do not support the direct decarboxylation mechanism that has been proposed for the enzyme. However, in the context of QM/MM calculations, it was found that the size of the QM region has a dramatic effect on the calculated reaction barrier.

OMP decarboxylase--An enigma persists

In 1995, Radzicka and Wolfenden reported that the rate enhancement produced by orotidine 5'-phosphate decarboxylase (ODCase) approaches 10(17), making this enzyme the most effective pure protein catalyst known in Nature [A. Radzicka, R. Wolfenden, Science 267 (1995) 90-93]. Over the last 12 years, there have been many hypotheses put forward to explain that impressive effect. In this perspective, we provide a summary of the reaction pathways under consideration for ODCase, highlight the supporting and refuting data, and suggest experiments designed to further test each of the candidate pathways.

Aminoethylation in model peptides reveals conditions for maximizing thiol specificity

Control of pH in aminoethylation reactions is critical for maintaining high selectivity towards cysteine modification. Measurement of aminoethylation rate constants by liquid chromatography mass spectrometry demonstrates reaction selectivity of cysteine>>amino-terminus>>histidine. Lysine and methionine were not reactive at the conditions used. For thiol modification, the acid/base property of the gamma-thialysine residue measured by NMR results in a 1.15 decrease in pK(a) (relative to a lysine residue). NMR confirms ethylene imine is the reactive intermediate for alkylation of peptide nucleophiles with bromoethylamine. Conversion of bromoethylamine into ethylene imine prior to exposure to the target thiol, provides a reagent that promotes selectivity by allowing precise control of reaction pH. Reaction selectivity plots of relative aminoethylation rates for cysteine, histidine, and N-terminus imine demonstrate increasing alkaline conditions favors thiol modification. When applied to protein modification, the conversion of bromoethylamine into ethylene imine and buffering at alkaline pH will allow optimal cysteine residue aminoethylation.

A proficient enzyme: insights on the mechanism of orotidine monophosphate decarboxylase from computer simulations

Decarboxylation of orotidine 5'-monophosphate (Omp) to uridine 5'-monophosphate by orotidine 5'-monophosphate decarboxylase (ODCase) is currently the object of vivid debate. Here, we clarify its enzymatic activity with long time scale classical molecular dynamics and hybrid ab initio Car-Parrinello/molecular mechanics simulations. The lack of structural (experimental) information on the ground state of ODCase/Omp complex is overcome by a careful construction of the model and the analysis of three different strains of the enzyme. We find that the ODCase/substrate complex is characterized by a very stable charged network Omp-Lys-Asp-Lys-Asp, which is incompatible with the previously proposed direct decarboxylation driven by a ground-state destabilization. A direct decarboxylation induced by a transition-state electrostatic stabilization is consistent with our findings. The calculated activation free energy for the direct decarboxylation with the formation of a C6 carboanionic intermediate yields an overall rate enhancement by the enzyme (k(cat)/k(wat) = 3.5 x 10(16)) in agreement with experiments (k(cat)/k(wat) = 1.7 x 10(17)). The decarboxylation is accompanied by the movement of a fully conserved lysine residue toward the developing negative charge at the C6 position.

Theoretical Studies of the Effect of Thio Substitution on Orotidine Monophosphate Decarboxylase Substrates

[reaction: see text] The effect of replacing carbonyl oxygens with sulfur in a series of orotidine 5'-monophosphate decarboxylase (ODCase) substrates was studied computationally. Previous experimental results indicate that while 2-thio-orotidine 5'-monophosphate (2-thio-OMP) is a poor substrate for ODCase, 4-thio-orotidine 5'-monophosphate (4-thio-OMP) binds to ODCase, and the resultant k(cat) is measurable. Energetics calculations on 2-thio-1-methyl-orotate and 4-thio-1-methyl-orotate (as models for the 2- and 4-thio-OMPs) indicate that mechanisms involving proton transfer to the 2- or 4-site, regardless of substrate and regardless of whether the 2- or 4-position is a carbonyl or thiocarbonyl, are energetically favorable, as compared to direct decarboxylation without proton transfer. Proton transfer to the 4-site during decarboxylation is found to be energetically more favorable than 2-protonation. Each thiocarbonyl is also found to be more basic than its carbonyl counterpart. Therefore, if 2- or 4-proton transfer is the operative catalytic pathway, energetics alone would not explain why 2-thio-orotidine 5'-monophosphate is a poor ODCase substrate. Conformational preferences for a series of ODCase substrates were also examined computationally. Specifically, the energies and Boltzmann probabilities of the conformers resulting from rotation about the C1'-N1 bond (O4'-C1'-N1-C2 rotation from 0 degrees to 360 degrees ) were calculated. It was found that a calculated preference for the syn versus the anti nucleoside conformation correlates to an experimentally better substrate: the OMP and 4-thio-OMP models show a preference for syn conformations, whereas the 2-thio-OMP (the only substrate of the three OMPs that is experimentally found to bind poorly) model shows a preference for an anti conformation. The same rough correlation was found for a series of ODCase inhibitors; that is, a preference for the syn conformation correlates to a better inhibitor. This result is of interest and points to the possibility that the ability for a substrate to bind well to ODCase may be related to its tendency to favor the syn conformation.

Hydrogen isotope tracing in the reaction of orotidine-5'-monophosphate decarboxylase

The mechanism of the enzyme orotidine-5(')-monophosphate decarboxylase (OMP decarboxylase, ODCase) is not fully characterized; some of the proposed mechanisms suggest the possibility of hydrogen rearrangement (shift from C5 to C6 or loss of H5 to solvent) during catalysis. In this study, we sought mechanistic information for the ODCase reaction by examining the extent of hydrogen exchange in the product uridine-5(')-monophosphate, in combination with ODCase, at the H5 and H6 positions. In a subsequent experiment, partially deuterated OMP was prepared, and the extent of 2H5 rearrangement or loss to solvent was examined by integration of 1H nuclear magnetic resonance signals in the substrate and the resulting enzymatically decarboxylated product. The absence of detectable hydrogen exchange in these experiments limits somewhat the possible mechanisms for ODCase catalysis.

Catalytic proficiency: the unusual case of OMP decarboxylase

Enzymes are called upon to differ greatly in the difficulty of the tasks that they perform. The catalytic proficiency of an enzyme can be evaluated by comparing the second-order rate constant (kcat/Km) with the rate of the spontaneous reaction in neutral solution in the absence of a catalyst. The proficiencies of enzymes, measured in this way, are matched by their affinity constants for the altered substrate in the transition state. These values vary from approximately approximately 10(9) M(-1) for carbonic anhydrase to approximately 10(23) M(-1) for yeast orotidine 5'-phosphate decarboxylase (ODCase). ODCase turns its substrate over with a half-time of 18 ms, in a reaction that proceeds in its absence with a half-time of 78 million years in neutral solution. ODCase differs from other decarboxylases in that its catalytic activity does not depend on the presence of metals or other cofactors, or on the formation of a covalent bond to the substrate. Several mechanisms of transition state stabilization are considered in terms of ODCase crystal structures observed in the presence and absence of bound analogs of the substrate, transition state, and product. Very large connectivity effects are indicated by the results of experiments testing how transition state stabilization is affected by the truncation of binding determinants of the substrate and the active site.

The acidity of uracil and uracil analogs in the gas phase: four surprisingly acidic sites and biological implications

The gas phase acidities of a series of uracil derivatives (1-methyluracil, 3-methyluracil, 6-methyluracil, 5,6-dimethyluracil, and 1,3-dimethyluracil) have been bracketed to provide an understanding of the intrinsic reactivity of uracil. The experiments indicate that in the gas phase, uracil has four sites more acidic than water. Among the uracil analogs, the N1-H sites have deltaH(acid) values of 331-333 kcal mol(-1); the acidity of the N3 sites fall between 347-352 kcal mol(-1). The vinylic C6 in 1-methyluracil and 3-methyluracil brackets to 363 kcal mol(-1), and 369 kcal mol(-1) in 1,3-dimethyluracil; the C5 of 1,3-dimethyluracil brackets to 384 kcal mol(-1). Calculations conducted at B3LYP/6-31+G* are in agreement with the experimental values. The bracketing of several of these sites involved utilization of an FTMS protocol to measure the less acidic site in a molecule that has more than one acidic site, establishing the generality of this method. In molecules with multiple acidic sites, only the two most acidic sites were bracketable, which is attributable to a kinetic effect. The measured acidities are in direct contrast to in solution, where the two most acidic sites of uracil (N1 and N3) are indifferentiable. The vinylic C6 site is also particularly acidic, compared to acrolein and pyridine. The biological implications of these results, particularly with respect to enzymes for which uracil is a substrate, are discussed.

Chemical-modification rescue assessed by mass spectrometry demonstrates that gamma-thia-lysine yields the same activity as lysine in aldolase

The role of active site residues in fructose 1,6-bisphosphate aldolase is investigated by chemical-modification rescue. An active-site mutation, K107C, is constructed in a background where the four solvent-accessible cysteine residues are converted to alanine. The resulting mutant, tetK107C, when reacted with bromoethylamine (BrEA), shows a 40-fold increase in activity (to 80% that of wild type). Determination of the sites and their degree of modification using electrospray ionization Fourier transform mass spectrometry (ESI-FTMS) is developed, allowing correlation of activity after chemical modification rescue to the degree of modification. The stoichiometry of the reaction is 2.5 aminoethylations per subunit, as measured by ESI-FTMS. Protein modification with a double-labeled mix (1:1) of natural abundance isotope (d(0)-BrEA) and 2-bromoethyl-1,1,2,2-d4-amine hydrobromide (d(4)-BrEA), followed by dialysis and trypsin digestion, shows aminoethylated peptides as "twin peptides" separated by four mass units in ESI-FTMS analysis. Using this detection procedure under nondenaturing (native) conditions, C107 is aminoethylated, whereas the four buried thiols remain unlabeled. Aminoethylation of other residues is observed, and correlates with those peptides containing histidine, methionine, and/or the amino terminus. Quantification of the aminoethylation reaction is achieved by labeling with nondeuterated d(0)-BrEA under denaturing conditions following double labeling under native conditions. In addition to complete labeling all five thiols, the intensity of the d(0)-BrEA peak for C107 containing peptides increases, and the change in the d(0)/d(4) ratio between native and denaturing conditions shows 82 +/- 4.5% aminoethylation at C107. This correlation of modification with the recovered activity, indicates that gamma-thia-lysine replaces lysine in the catalytic mechanism. Kinetic constants measured for the rescued K107C mutant enzyme with the substrates fructose 1-phosphate and fructose 1,6-bisphosphate are consistent with the role of the positively charged lysine binding to the C6-phosphate. ESI-FTMS, combined with this double-labeling procedure, allows precise identification of sites and measurement of degree of protein modification.

An alternative explanation for the catalytic proficiency of orotidine 5'-phosphate decarboxylase

Orotidine 5'-phosphate decarboxylase (ODCase) is the most proficient enzyme known, enhancing the rate of decarboxylation of orotidine 5'-phosphate (OMP) by a factor of 10(17), which corresponds to a DeltaDeltaG++ of approximately 24 kcal/mol. Ground-state destabilization through local electrostatic stress has been recently proposed as the basis of catalytic rate enhancement for a mechanism that is the same as in solution. We have carried out gas-phase ab initio quantum mechanical calculations combined with a free energy method, a continuum solvent model, and molecular dynamics simulations to assess an alternative mechanism. Although we are not able to reproduce the experimentally observed DeltaDeltaG++ quantitatively, we present evidence that this DeltaDeltaG++ is very large, in the range found experimentally. We thus conclude that the preferred mechanism may well be different from that in solution, involving an equilibrium pre-protonation of OMP C5 by a catalytic lysine residue that greatly reduces the barrier to subsequent decarboxylation.

Theoretical studies of mechanisms and kinetic isotope effects on the decarboxylation of orotic acid and derivatives

The mechanism of orotidine 5'-monophosphate decarboxylase was studied computationally by using the decarboxylation of orotic acid analogues as model systems. These calculations indicate that mechanisms involving proton transfer to the 2-oxygen or the 4-oxygen are energetically favorable, as compared to direct decarboxylation without proton transfer, for a series of model compounds where N1 is substituted with respectively H, CH(3), and a tetrahydrofuran moiety. Proton transfer to the 4-oxygen during decarboxylation is found to be energetically more favorable than 2-protonation, which is attributable to both the 4-oxygen site being more basic and an apparent intrinsic preference for the 4-protonation pathway. (15)N isotope effect calculations were also conducted, and compared to experimental (15)N isotope effects previously measured at N1 by Rishavy and Cleland (Biochemistry 2000, 39, 4569-4574). The theoretical isotope effects establish, for the first time, that the experimental (15)N isotope effect is consistent with decarboxylation without protonation, as well as with decarboxylation with protonation, at either O2 or at O4. Furthermore, we propose herein an isotope measurement that could potentially distinguish among mechanisms involving protonation from those that do not involve proton transfer.

Dissecting a charged network at the active site of orotidine-5'-phosphate decarboxylase

The crystal structure of yeast orotidine-5'-phosphate decarboxylase in complex with the postulated transition state analog, 6-hydroxyuridine-5'-phosphate, reveals contacts between this inhibitor and a novel quartet of charged residues (Lys-59, Asp-91, Lys-93, and Asp-96) within the active site. The structure also suggests a possible interaction between O2 of the 6-hydroxyuridine-5'-phosphate pyrimidine ring and Gln-215. Here we report the results of mutagenesis of each of the charged active site residues and Gln-215. The activities of the Q215A and wild-type enzymes were equal indicating that any interactions between this residue and the pyrimidine ring are dispensable for efficient decarboxylation. For the D91A and K93A mutant enzymes, activity was reduced by more than 5 orders of magnitude and substrate binding could not be detected by isothermal calorimetry. For the D96A mutant enzyme, k(cat) was reduced by more than 5 orders of magnitude, and isothermal calorimetry indicated an 11-fold decrease in the affinity of this enzyme for the substrate in the ground state. For the K59A enzyme, k(cat) was reduced by a factor of 130, and K(m) had increased by a factor of 900. These results indicate that the integrity of the network of charged residues is essential for transition state stabilization.

A reexamination of the substrate utilization of 2-thioorotidine-5'-monophosphate by yeast orotidine-5'-monophosphate decarboxylase

A potential alternate substrate for orotidine-5'-monophosphate decarboxylase, 2- thio-orotidine-5'-monophosphate, was synthesized enzymatically and purified by a modification of a previous account (K. Shostak, and M. E. Jones 1992, Biochemistry 31, 12155-12161). Characterization of the product was confirmed by mass spectrometry, (31)P NMR, and utilization by orotate phosphoribosyltransferase in the direction of pyrophosphorolysis. The previous work probably did not result in the purification of the desired compound, as evidenced by our observation of 2-thioOMP's sensitivity to high temperature, as used previously. Using a very sensitive HPLC assay for the potential decarboxylated product 2-thioUMP, no measurable activity of ODCase toward the alternate substrate was observed, representing a decarboxylation rate decreased by 10(-7) from the k(cat) for ODCase toward OMP. Additionally, 2-thioOMP effects no inhibition of ODCase decarboxylation of OMP at a concentration of 50 microM, indicating a poor ability to bind to the ODCase active site. The results bear implications for proposed mechanisms for catalysis by ODCase.

The structural basis for the remarkable catalytic proficiency of orotidine 5'-monophosphate decarboxylase

The three-dimensional structures of orotidine 5'-monophosphate decarboxylases from four different organisms have been determined by X-ray crystallography. The structures reveal an active site in which the pyrimidine base and phosphate groups are rigidly held in place. Surprisingly, both pyrimidine carbonyl groups are hydrogen bonded to amide groups, rather than to strong active site acids, as was previously predicted. The positioning of a conserved aspartate sidechain close to the substrate carboxylate and a conserved lysine ammonium group close to the C6 of the pyrimidine suggests a novel mechanism to explain the extreme catalytic proficiency of this enzyme.

Cloning and characterization of ftsZ and pyrF from the archaeon Thermoplasma acidophilum

To characterize cytoskeletal components of archaea, the ftsZ gene from Thermoplasma acidophilum was cloned and sequenced. In T. acidophilum ftsZ, which is involved in cell division, was found to be in an operon with the pyrF gene, which encodes orotidine-5'-monophosphate decarboxylase (ODC), an essential enzyme in pyrimidine biosynthesis. Both ftsZ and pyrF from T. acidophilum were expressed in Escherichia coli and formed functional proteins. FtsZ expression in wild-type E. coli resulted in the filamentous phenotype characteristic of ftsZ mutants. T. acidophilum pyrF expression in an E. coli mutant lacking pyrF complemented the mutation and rescued the strain. Sequence alignments of ODCs from archaea, bacteria, and eukarya reveal five conserved regions, two of which have homology to 3-hexulose-6-phosphate synthase (HPS), suggesting a common substrate recognition and binding motif.

Electrostatic stress in catalysis: structure and mechanism of the enzyme orotidine monophosphate decarboxylase

Orotidine 5'-monophosphate decarboxylase catalyzes the conversion of orotidine 5'-monophosphate to uridine 5'-monophosphate, the last step in biosynthesis of pyrimidine nucleotides. As part of a Structural Genomics Initiative, the crystal structures of the ligand-free and the6-azauridine 5'-monophosphate-complexed forms have been determined at 1.8 and 1.5 A, respectively. The protein assumes a TIM-barrel fold with one side of the barrel closed off and the other side binding the inhibitor. A unique array of alternating charges (Lys-Asp-Lys-Asp) in the active site prompted us to apply quantum mechanical and molecular dynamics calculations to analyze the relative contributions of ground state destabilization and transition state stabilization to catalysis. The remarkable catalytic power of orotidine 5'-monophosphate decarboxylase is almost exclusively achieved via destabilization of the reactive part of the substrate, which is compensated for by strong binding of the phosphate and ribose groups. The computational results are consistent with a catalytic mechanism that is characterized by Jencks's Circe effect.

The crystal structure and mechanism of orotidine 5'-monophosphate decarboxylase

The crystal structure of Bacillus subtilis orotidine 5'-monophosphate (OMP) decarboxylase with bound uridine 5'-monophosphate has been determined by multiple wavelength anomalous diffraction phasing techniques and refined to an R-factor of 19.3% at 2.4 A resolution. OMP decarboxylase is a dimer of two identical subunits. Each monomer consists of a triosephosphate isomerase barrel and contains an active site that is located across one end of the barrel and near the dimer interface. For each active site, most of the residues are contributed by one monomer with a few residues contributed from the adjacent monomer. The most highly conserved residues are located in the active site and suggest a novel catalytic mechanism for decarboxylation that is different from any previously proposed OMP decarboxylase mechanism. The uridine 5'-monophosphate molecule is bound to the active site such that the phosphate group is most exposed and the C5-C6 edge of the pyrimidine base is most buried. In the proposed catalytic mechanism, the ground state of the substrate is destabilized by electrostatic repulsion between the carboxylate of the substrate and the carboxylate of Asp60. This repulsion is reduced in the transition state by shifting negative charge from the carboxylate to C6 of the pyrimidine, which is close to the protonated amine of Lys62. We propose that the decarboxylation of OMP proceeds by an electrophilic substitution mechanism in which decarboxylation and carbon-carbon bond protonation by Lys62 occur in a concerted reaction.

Anatomy of a proficient enzyme: the structure of orotidine 5'-monophosphate decarboxylase in the presence and absence of a potential transition state analog

Orotidine 5'-phosphate decarboxylase produces the largest rate enhancement that has been reported for any enzyme. The crystal structure of the recombinant Saccharomyces cerevisiae enzyme has been determined in the absence and presence of the proposed transition state analog 6-hydroxyuridine 5'-phosphate, at a resolution of 2.1 A and 2.4 A, respectively. Orotidine 5'-phosphate decarboxylase folds as a TIM-barrel with the ligand binding site near the open end of the barrel. The binding of 6-hydroxyuridine 5'-phosphate is accompanied by protein loop movements that envelop the ligand almost completely, forming numerous favorable interactions with the phosphoryl group, the ribofuranosyl group, and the pyrimidine ring. Lysine-93 appears to be anchored in such a way as to optimize electrostatic interactions with developing negative charge at C-6 of the pyrimidine ring, and to donate the proton that replaces the carboxylate group at C-6 of the product. In addition, H-bonds from the active site to O-2 and O-4 help to delocalize negative charge in the transition state. Interactions between the enzyme and the phosphoribosyl group anchor the pyrimidine within the active site, helping to explain the phosphoribosyl group's remarkably large contribution to catalysis despite its distance from the site of decarboxylation.

The critical active-site amine of the human 8-oxoguanine DNA glycosylase, hOgg1: direct identification, ablation and chemical reconstitution

BACKGROUND

Base-excision DNA repair (BER) is the principal pathway responsible for the removal of aberrant, genotoxic bases from the genome and restoration of the original sequence. Key components of the BER pathway are DNA glycosylases, enzymes that recognize aberrant bases in the genome and catalyze their expulsion. One major class of such enzymes, glycosylase/lyases, also catalyze scission of the DNA backbone following base expulsion. Recent studies indicate that the glycosylase and lyase functions of these enzymes are mechanistically unified through a common amine-bearing residue on the enzyme, which acts as both the electrophile that displaces the aberrant base and an electron sink that facilitates DNA strand scission through imine (Schiff base)/conjugate elimination chemistry. The identity of this critical amine-bearing residue has not been rigorously established for any member of a superfamily of BER glycosylase/lyases.

RESULTS

Here, we report the identification of the active-site amine of the human 8-oxoguanine DNA glycosylase (hOgg1), a human BER superfamily protein that repairs the mutagenic 8-oxoguanine lesion in DNA. We employed Edman sequencing of an active-site peptide irreversibly linked to substrate DNA to identify directly the active-site amine of hOgg1 as the epsilon-NH2 group of Lys249. In addition, we observed that the repair-inactive but recognition-competent Cys249 mutant (Lys249-->Cys) of hOgg1 can be functionally rescued by alkylation with 2-bromoethylamine, which functionally replaces the lysine residue by generating a gamma-thia-lysine.

CONCLUSIONS

This study provides the first direct identification of the active-site amine for any DNA glycosylase/lyase belonging to the BER superfamily, members of which are characterized by the presence of a helix-hairpin-helix-Gly/Pro-Asp active-site motif. The critical lysine residue identified here is conserved in all members of the BER superfamily that exhibit robust glycosylase/lyase activity. The ability to trigger the catalytic activity of the Lys249-->Cys mutant of hOgg1 by treatment with the chemical inducer 2-bromoethylamine may permit snapshots to be taken of the enzyme acting on its substrate and could represent a novel strategy for conditional activation of catalysis by hOgg1 in cells.

A proficient enzyme revisited: the predicted mechanism for orotidine monophosphate decarboxylase

A mechanism is proposed to explain the activity of orotidine 5'-monophosphate decarboxylase (ODCase). This enzyme is the one of the most proficient known, with a catalytic proficiency (kcat/Km)/knon = 10(23) M-1. Quantum mechanical calculations predict a mechanism involving a stabilized carbene intermediate, which represents a previously unrecognized mode of enzymatic activity for ODCase. The proposed mechanism involves proton transfer from a weak acid (pKa = 7, where Ka is the acid constant) concerted with decarboxylation, in a nonpolar enzyme environment. Such a mechanism makes possible different approaches to the design of ODCase inhibitors. Furthermore, the prediction that general acid catalysis may only be effective in low dielectric media is of general significance for understanding the activity of many enzymes.

Intrinsic activity and stability of bifunctional human UMP synthase and its two separate catalytic domains, orotate phosphoribosyltransferase and orotidine-5'-phosphate decarboxylase

Human UMP synthase is a bifunctional protein containing two separate catalytic domains, orotate phosphoribosyltransferase (EC 2.4.2.10) and orotidine-5'-phosphate decarboxylase (EC 4.1.1.23). These studies address the question of why the last two reactions in pyrimidine nucleotide synthesis are catalyzed by a bifunctional enzyme in mammalian cells, but by two separate enzymes in microorganisms. From existing data on subunit associations of the respective enzymes and calculations showing the molar concentration of enzyme to be far lower in mammalian cells than in microorganisms, we hypothesize that the covalent union in UMP synthase stabilizes the domains containing the respective catalytic centers. Evidence supporting this hypothesis comes from studies of stability of enzyme activity in vitro, at physiological concentrations, of UMP synthase, the two isolated catalytic domains prepared by site-directed mutagenesis of UMP synthase, and the yeast ODCase. The two engineered domains have activities very similar to the native UMP synthase, but unlike the bifunctional protein, the domains are quite unstable under conditions promoting the dissociated monomer.

A proficient enzyme

Orotic acid is decarboxylated with a half-time (t1/2) of 78 million years in neutral aqueous solution at room temperature, as indicated by reactions in quartz tubes at elevated temperatures. Spontaneous hydrolysis of phosphodiester bonds, such as those present in the backbone of DNA, proceeds even more slowly at high temperatures, but the heat of activation is less positive, so that dimethyl phosphate is hydrolyzed with a t1/2 of 130,000 years in neutral solution at room temperature. These values extend the known range of spontaneous rate constants for reactions that are also susceptible to catalysis by enzymes to more than 14 orders of magnitude. Values of the second-order rate constant kcat/Km for the corresponding enzyme reactions are confined to a range of only 600-fold, in contrast. Orotidine 5'-phosphate decarboxylase, an extremely proficient enzyme, enhances the rate of reaction by a factor of 10(17) and is estimated to bind the altered substrate in the transition state with a dissociation constant of less than 5 x 10(-24) M.

Orotidine-5'-monophosphate decarboxylase from Pseudomonas aeruginosa PAO1: cloning, overexpression, and enzyme characterization

Orotidine-5'-monophosphate decarboxylase (OMPdecase) catalyzes the final step in pyrimidine biosynthesis, the conversion of orotidine-5'-monophosphate (OMP) to uridine-5'-monophosphate. The pyrF gene, encoding OMPdecase, was isolated from a chromosomal library of Pseudomonas aeruginosa PAO1 by screening for complementation of an Escherichia coli and a P. aeruginosa pyrF mutant. The nucleotide sequence of a 2510-bp chromosomal DNA fragment, complementing both strains, was determined (EMBL accession number X65613). On this a 696-bp open reading frame capable of encoding the 24 kDa OMPdecase was identified. Despite a generally good correspondence to other OMPdecase sequences, the P. aeruginosa gene was unique in that it did not constitute part of an operon. The pyrF gene was amplified by polymerase chain reaction, overexpressed in the pT7-7/E. coli BL21(DE3) system and purified to near electrophoretic homogeneity by anion exchange chromatography. Characterization of the purified enzyme revealed the following data, a Km value for OMP of 9.91 microM and an isoelectric point of 6.65. No major decrease in enzyme activity was observed in a pH range between 7.8 and 10.2. Gel electrophoresis under nondenaturing conditions suggested that the native form of OMPdecase is the dimer.

Selection of catalytic antibodies for a biosynthetic reaction from a combinatorial cDNA library by complementation of an auxotrophic Escherichia coli: antibodies for orotate decarboxylation

Antibodies capable of decarboxylating orotate were sought by immunization with a hapten designed to elicit antibodies with combining sites that resemble the orotate-binding and catalytic portion of the active site of the enzyme orotidine 5'-monophosphate (OMP) decarboxylase (orotidine-5'-monophosphate carboxy-lyase, EC 4.1.1.23). Active recombinant antibody fragments (Fabs) were selected from a combinatorial cDNA library by complementation of a pyrF strain of Escherichia coli and growth of the library-expressing cells on pyrimidine-free medium. In this biological screen, a sufficiently active antibody from the library would decarboxylate orotate to produce uracil, a pyrimidine source for the auxotroph, and would provide the cells with a growth advantage compared to cells without an active antibody. Six recombinant Fabs yielded identifiable colonies in a screen of 16,000 transformants. To enhance its stability and expression level, one of the six positive fragments was converted into single-chain form. In this form, the antibody fragment conferred a definite growth advantage to the auxotroph that was eliminated when the hapten was included in the medium. The purified single-chain antibody displayed orotate decarboxylase activity in vitro, as determined by a 14CO2 displacement assay. The specific activity of the antibody is approximately 10(-7) times that of naturally occurring OMP decarboxylase, but this antibody-catalyzed rate is estimated to be 10(8) times the background rate. The results offer the potential to use these methods to obtain catalytic antibodies for other biosynthetic reactions as well as to assess the effectiveness of the hapten transition state or active site analog in eliciting antibody catalysts.

Low-barrier hydrogen bonds and enzymic catalysis

Formation of a short (less than 2.5 angstroms), very strong, low-barrier hydrogen bond in the transition state, or in an enzyme-intermediate complex, can be an important contribution to enzymic catalysis. Formation of such a bond can supply 10 to 20 kilocalories per mole and thus facilitate difficult reactions such as enolization of carboxylate groups. Because low-barrier hydrogen bonds form only when the pKa's (negative logarithm of the acid constant) of the oxygens or nitrogens sharing the hydrogen are similar, a weak hydrogen bond in the enzyme-substrate complex in which the pKa's do not match can become a strong, low-barrier one if the pKa's become matched in the transition state or enzyme-intermediate complex. Several examples of enzymatic reactions that appear to use this principle are presented.