Formation of catalytically active cross-species heterodimers of thymidylate synthase from <Emphasis Type="Italic">Plasmodium falciparum</Emphasis> and <Emphasis Type="Italic">Plasmodium vivax</Emphasis>

Thymidylate synthase (TS) of Plasmodium dihydrofolate reductase-thymidylate synthase (DHFR-TS) functions as a homodimeric enzyme with two active sites located near the subunit interface. The dimerization is essential for catalysis, since the active site of each subunit contains amino acid residues contributed from the other TS domain. In P. falciparum DHFR-TS, it has been shown that the active sites require Cys-490 from one domain and Arg-470 donated from the other domain. Mutants of these two series can complement one another giving rise to active enzyme. Here, the potential to form cross-species heterodimers between P. falciparum and P. vivax TS has been explored. Formation of cross-species heterodimer was tested by co-transformation of TS-inactive Cys-490 mutants of P. falciparum or P. vivax with corresponding TS-inactive Arg-486 mutants of P. vivax or P. falciparum into thymidine-requiring Escherichia coli. Active heterodimers were detected by subunit complementation and 6-[³H]-FdUMP binding assays. All combinations of the mutants tested, except for (Pf)R470A+(Pv)C506Y, were able to form catalytically active cross-species heterodimers. The single active site formed by (Pf)R470D+(Pv)C506Y and (Pv)R486D+(Pf)C490A pairs of cross-species heterodimers has k _cat and K _m values similar to those of intra-species heterodimers of P. falciparum and P. vivax. This is the first report to demonstrate that the TS subunit interface between Plasmodium species is sufficiently conserved to allow formation of fully active cross-species heterodimer.     

Energetic contributions of four arginines to phosphate-binding in thymidylate synthase are more than additive and depend on optimization of "effective charge balance"

In thymidylate synthase, four conserved arginines provide two hydrogen bonds each to the oxygens of the phosphate group of the substrate, 2'-deoxyuridine-5'-monophosphate. Of these, R23, R178, and R179 are far removed from the site of methyl transfer and contribute to catalysis solely through binding and orientation of ligands. These arginines can be substituted by other residues, while still retaining more than 1% activity of the wild-type enzyme. We compared the kinetics and determined the crystal structures of dUMP complexes of three of the most active, uncharged single mutants of these arginines, R23I, R178T, and R179T, and of double mutants (R23I, R179T) and (R178T, R179T). The dramatically higher K(m) for R178T compared to the other two single mutants arises from the effects of R178 substitution on the orientation of dUMP; 10-15-fold increases in for R23I and R178T reflect the role of these residues in stabilizing the closed conformation of TS in ternary complexes. The free energy for productive dUMP binding, DeltaG(S), increases by at least 1 kcal/mol for each mutant, even when dUMP orientation and mobility in the crystal structure is the same as in wild-type enzyme. Thus, the four arginines do not contribute excess positive charge to the PO(4)(-2) binding site; rather, they ideally complement the charge and geometry of the phosphate moiety. More-than-additive increases in DeltaG(S) seen in the double mutants are consistent with quadratic increases in DeltaG(S) predicted for deviations from ideal electrostatic interactions and may also reflect cooperative binding of the arginines to the phosphate oxygens.     

The Power of Two: ARGININE 51 AND ARGININE 239* FROM A NEIGHBORING SUBUNIT ARE ESSENTIAL FOR CATALYSIS IN α-AMINO-β-CARBOXYMUCONATE-?-SEMIALDEHYDE DECARBOXYLASE*

Although the crystal structure of α-amino-β-carboxymuconate-ϵ-semialdehyde decarboxylase from Pseudomonas fluorescens was solved as a dimer, this enzyme is a mixture of monomer, dimer, and higher order structures in solution. In this work, we found that the dimeric state, not the monomeric state, is the functionally active form. Two conserved arginine residues are present in the active site: Arg-51 and an intruding Arg-239* from the neighboring subunit. In this study, they were each mutated to alanine and lysine, and all four mutants were catalytically inactive. The mutants were also incapable of accommodating pyridine-2,6-dicarboxylic acid, a competitive inhibitor of the native enzyme, suggesting that the two Arg residues are involved in substrate binding. It was also observed that the decarboxylase activity was partially recovered in a heterodimer hybridization experiment when inactive R51(A/K) and R239(A/K) mutants were mixed together. Of the 20 crystal structures obtained from mixing inactive R51A and R239A homodimers that diffracted to a resolution lower than 3.00 Å, two structures are clearly R51A/R239A heterodimers and belong to the C2 space group. They were refined to 1.80 and 2.00 Å resolutions, respectively. Four of the remaining crystals are apparently single mutants and belong to the P4₂2₁2 space group. In the heterodimer structures, one active site is shown to contain dual mutation of Ala-51 and Ala-239*, whereas the other contains the native Arg-51 and Arg-239* residues, identical to the wild-type structure. Thus, these observations provide the foundation for a molecular mechanism by which the oligomerization state of α-amino-β-carboxymuconate-ϵ-semialdehyde decarboxylase could regulate the enzyme activity.     

Replacement set mutagenesis of the four phosphate-binding arginine residues of thymidylate synthase

Arginines R23, R178, R179 and R218 in thymidylate synthase (TS, EC 2. 1.1.45) are hydrogen bond donors to the phosphate moiety of the substrate, dUMP. In order to investigate how these arginines contribute to enzyme function, we prepared complete replacement sets of mutants at each of the four sites in Lactobacillus casei TS. Mutations of R23 increase K:(m) for dUMP 2-20-fold, increase K:(m) for cofactor 8-40-fold and decrease k(cat) 9-20-fold, reflecting the direct role of the R23 side chain in binding and orienting the cofactor in ternary complexes of the enzyme. Mutations of R178 increase K:(m) for dUMP 40-2000-fold, increase K:(m) for cofactor 3-20-fold and do not significantly affect k(cat). These results are consistent with the fact that this residue is an integral part of the dUMP-binding wall and contributes to the orientation and ordering of several other dUMP binding residues. Kinetic parameters for all R179 mutations except R179P were not significantly different from wild-type values, reflecting the fact that this external arginine does not directly contact the cofactor or other ligand-binding residues. R218 is essential for the structure of the catalytic site and all mutations of this arginine except R218K were inactive.     

Intersubunit location of the active site of farnesyl diphosphate synthase: reconstruction of active enzymes by hybrid-type heteromeric dimers of site-directed mutants

Farnesyl diphosphate synthase is a homodimer of subunits having typically two aspartate-rich motifs with two sets of substrate binding sites for an allylic diphosphate and isopentenyl diphosphate per molecule of a homodimeric enzyme. To determine whether each subunit contains an independent active site or whether the active sites are created by intersubunit interaction, we constructed several expression plasmids that overproduce hybrid-type heterodimers of Bacillus stearothermophilus FPP synthases constituting different types of mutated monomers, which exhibit little catalytic activity as homodimers, by combining two tandem fps genes for the manipulated monomer subunit with a highly efficient promoter trc within an overexpression pTrc99A plasmid. A heterodimer of a combination of subunits of the wild type and of R98E, a mutant subunit which exhibits little enzymatic activity as a dimer form (R98E)(2), exhibited 78% of the activity of the wild-type homodimer enzyme, (WT)(2). Moreover, when a hybrid-type heterodimeric dimer of FPP synthase mutant subunits (R98E/F220A) was prepared, the FPP synthase activity was 18- and 390-fold of that of each of the almost inactive mutants as a dimeric enzymes, (R98E)(2) and (F220A)(2) [Koyama, T., et al. (1995) Biochem. Biophys. Res. Commun. 212, 681-686], respectively. These results suggest that the subunits of the FPP synthase interact with each other to form a shared active site in the homodimer structure rather than an independent active site in each subunit.     

Parameters affecting the restoration of activity to inactive mutants of thymidylate synthase via subunit exchange: further evidence that thymidylate synthase is a half-of-the-sites activity enzyme

In a previous study we demonstrated that Escherichia coli thymidylate synthase activity could be restored completely by incubating basically inactive mutants of this enzyme at room temperature with R(126)E, another inactive mutant [Maley, F., Pedersen-Lane, J., and Changchien, L.-M. (1995) Biochemistry 34, 1469-1474]. Since only one of the enzyme's two subunits possessed a functional active site and the restoration of activity could be titrated to be equivalent to that of the wild-type enzyme's specific activity, it was proposed that thymidylate synthase was a half-of-the-sites activity enzyme. We now provide additional support for this thesis by presenting an in-depth analysis of some conditions affecting the restoration of enzyme activity. For this purpose, we employed two mutants with marginal thymidylate synthase activity, Y(94)A and R(126)E. The parameters that were examined included pH, concentration of protein, temperature, and urea concentration, all of which influenced the rate of activity restoration. It was found, surprisingly, that by maintaining the amount of each protein constant, while increasing the volume of solution, the rate and total activity restored was greatly enhanced. Increasing the pH from 6.0 to 9.0 markedly increased the rate at which the optimal activity was restored, as did increasing the temperature from 4 to 40 degrees C. A similar effect was obtained when the incubation of the mutants was conducted at 4 degrees C in the presence of 1.5 M urea, a temperature at which activity is restored extremely slowly. Raising the pH to 9.0 resulted in an almost instantaneous restoration of activity at 4 degrees C. The manner in which thymidylate synthase activity is restored from the mutants in the presence of varying concentrations of ethanol, ethylene glycol, and glycerol suggests that changes in subunit interaction and enzyme conformation are in part responsible for the observed differences. Most significantly, at solution levels of 10%, ethanol was found to activate, while ethylene glycol inhibited slightly and glycerol was somewhat more inhibitory. At a concentration of 20%, ethanol inhibited rather strikingly, ethylene glycol was slightly more inhibitory than at 10%, and glycerol was strongly inhibitory. Since the net result of these findings is the suggestion that the restoration of thymidylate synthase activity is due to a separation of the mutant dimers into their respective subunits, followed by their recombination to an active heterodimer, evidence for this phenomenon was sought by separating the recombined dimers using nondenaturating polyacrylamide gel electrophoresis. Sequence analysis of the isolated homo- and heterodimers clearly demonstrated that the active enzyme is a product of subunit exchange, one that is very efficient relative to the wild-type enzyme, which did not exchange subunits unless denatured.     

Site-directed mutagenesis of arginine 179 of thymidylate synthase. A nonessential substrate-binding residue

X-ray structural studies have shown that Arg-179 of thymidylate synthase is complexed to bound inorganic phosphate or to the 5'-phosphate of the bound substrate dUMP. The importance of Arg-179 to the structure/function of thymidylate synthase is also indicated by its complete conservation among the 17 thymidylate synthases thus far sequenced. In the present work, Arg-179 has been replaced by Thr, Ala, Lys, and Glu using site-directed mutagenesis with a mixture of four synthetic oligonucleotides as primers. The mutant proteins complement thymidylate synthase-deficient Escherichia coli and show high enzyme activity. Each of these mutants has been purified to homogeneity, partially sequenced to verify the mutation, and has had its steady state kinetic parameters determined. The most significant effect of all mutations is localized to a decrease in the net rate of association of thymidylate synthase with dUMP; the Lys mutant also shows an apparent increase in the dissociation constant of the folate cofactor of the reaction. The high activity in the mutant enzymes is explained by "plasticity" of the enzyme and compensatory actions of the other Arg residues. Why the Arg-179 residue has been conserved during evolution remains an open question.     

Evidence for the existence of covalent nucleotide-thymidylate synthase complexes, identification of site of attachment, and enhancement by folates

The formation of covalent binary complexes of thymidylate synthase and its nucleotide substrate dUMP, product dTMP, and inhibitor, 5-fluorodeoxyuridylate (FdUMP) was investigated using the trichloroacetic acid precipitation method. It was observed that, in addition to FdUMP, both dUMP and dTMP were capable of covalent interactions with the enzyme in the absence of added folates. The presence of folate, dihydrofolate, or tetrahydrofolate (H4folate) was found to produce substantial enhancements in the covalent binding of both FdUMP and dUMP to the enzyme with H4folate being the most effective agent. Further, covalent binary complexes of the enzyme with the three radiolabeled nucleotides were isolated by trichloroacetic acid precipitation and subjected to CNBr cleavage. The active-site CNBr peptide was isolated by reverse phase high performance liquid chromatography, and the first five N-terminal amino acid residues were sequenced by the dansyl-Edman procedure. Each active site peptide obtained from the covalent binary complexes as well as that from the covalent inhibitory ternary complex formed from enzyme, FdUMP, and 5,10-methylene-H4folate exhibited an identical sequence of Ala-Leu-Pro-Pro-(X)-, and the 5th amino acid was found to be associated with radiolabeled nucleotide ligand. Dansyl-Edman sequence analysis of the active site CNBr peptide, derived from enzyme which had been treated with iodoacetic acid, gave a sequence of Ala-Leu-Pro-Pro-CmCys (where CmCys is carboxymethylcysteine), thus confirming the fact that the fifth residue from the N terminus is Cys-198. In all the cases, the active site Cys-198 residue was found to be covalently linked to the nucleotides. These results provide unequivocal proof that the covalent binary complexes of enzyme with dUMP and dTMP predicted in the catalytic reaction mechanism actually exist.     

Tryptophan 80 and leucine 143 are critical for the hydride transfer step of thymidylate synthase by controlling active site access

Mutant forms of thymidylate synthase (TS) with substitutions at the conserved active site residue, Trp 80, are deficient in the hydride transfer step of the TS reaction. These mutants produce a beta-mercaptoethanol (beta-ME) adduct of the 2'-deoxyuridine-5'-monophosphate (dUMP) exocyclic methylene intermediate. Trp 80 has been proposed to assist hydride transfer by stabilizing a 5,6,7,8-tetrahydrofolate (THF) radical cation intermediate [Barrett, J. E., Lucero, C. M., and Schultz, P. G. (1999) J. Am. Chem. Soc. 121, 7965-7966.] formed after THF changes its binding from the cofactor pocket to a putative alternate site. To understand the molecular basis of hydride transfer deficiency in a mutant in which Trp 80 was changed to Gly, we determined the X-ray structures of this mutant Escherichia coli TS complexed with dUMP and the folate analogue 10-propargyl-5,8-dideazafolate (CB3717) and of the wild-type enzyme complexed with dUMP and THF. The mutant enzyme has a cavity in the active site continuous with bulk solvent. This cavity, sealed from bulk solvent in wild-type TS by Leu 143, would allow nucleophilic attack of beta-ME on the dUMP C5 exocyclic methylene. The structure of the wild-type enzyme/dUMP/THF complex shows that THF is bound in the cofactor binding pocket and is well positioned to transfer hydride to the dUMP exocyclic methylene. Together, these results suggest that THF does not reorient during hydride transfer and indicate that the role of Trp 80 may be to orient Leu 143 to shield the active site from bulk solvent and to optimally position the cofactor for hydride transfer.     

The effect of Arg209 to Lys mutation in mouse thymidylate synthase

Mouse thymidylate synthase R209K (a mutation corresponding to R218K in Lactobacillus casei), overexpressed in thymidylate synthase-deficient Escherichia coli strain, was poorly soluble and with only feeble enzyme activity. The mutated protein, incubated with FdUMP and N(5,10)-methylenetetrahydrofolate, did not form a complex stable under conditions of SDS/polyacrylamide gel electrophoresis. The reaction catalyzed by the R209K enzyme (studied in a crude extract), compared to that catalyzed by purified wild-type recombinant mouse thymidylate synthase, showed the K(m) value for dUMP 571-fold higher and V(max) value over 50-fold (assuming that the mutated enzyme constituted 20% of total crude extract protein) lower. Thus the ratios k(cat, R209K)/k(cat, 'wild') and (k(cat, R209K)/K(m, R209K)(dUMP))/( k(cat, 'wild')/K(m, 'wild')(dUMP)) were 0.019 and 0.000032, respectively, documenting that mouse thymidylate synthase R209, similar to the corresponding L. casei R218, is essential for both dUMP binding and enzyme reaction.     

Structure, multiple site binding, and segmental accommodation in thymidylate synthase on binding dUMP and an anti-folate

The structure of Escherichia coli thymidylate synthase (TS) complexed with the substrate dUMP and an analogue of the cofactor methylenetetrahydrofolate was solved by multiple isomorphous replacement and refined at 1.97-A resolution to a residual of 18% for all data (16% for data greater than 2 sigma) for a highly constrained structure. All residues in the structure are clearly resolved and give a very high confidence in total correctness of the structure. The ternary complex directly suggests how methylation of dUMP takes place. C-6 of dUMP is covalently bound to gamma S of Cys-198(146) during catalysis, and the reactants are surrounded by specific hydrogen bonds and hydrophobic interactions from conserved residues. Comparison with the independently solved structure of unliganded TS reveals a large conformation change in the enzyme, which closes down to sequester the reactants and several highly ordered water molecules within a cavernous active center, away from bulk solvent. A second binding site for the quinazoline ring of the cofactor analogue was discovered by withholding addition of reducing agent during crystal storage. The chemical change in the protein is slight, and from difference density maps modification of sulfhydryls is not directly responsible for blockade of the primary site. The site, only partially overlapping with the primary site, is also surrounded by conserved residues and thus may play a functional role. The ligand-induced conformational change is not a domain shift but involves the segmental accommodation of several helices, beta-strands, and loops that move as units against the beta-sheet interface between monomers.     

The only active mutant of thymidylate synthase D169, a residue far from the site of methyl transfer,demonstrates the exquisite nature of enzyme specificity

Cysteine is the only variant of D169, a cofactor-binding residue in thymidylate synthase, that shows in vivo activity. The 2.4 A crystal structure of Escherichia coli thymidylate synthase D169C in a complex with dUMP and the antifolate CB3717 shows it to be an asymmetric dimer, with only one active site covalently bonded to dUMP. At the active site with covalently bound substrate, C169 S gamma adopts the roles of both carboxyl oxygens of D169, making a 3.6 A S...H[bond]N hydrogen bond to 3-NH of CB3717 and a 3.4 A water-mediated hydrogen bond to H212. Analogous hydrogen bonds formed during the enzyme reaction are important for cofactor binding and are postulated to contribute to catalysis. The C169 side chain is likely to be ionized, making it a better hydrogen bond acceptor than a neutral sulfhydryl group. At the second active site, C169 S gamma makes a shorter (3 A) hydrogen bond to the 3-NH of CB3717, CB3717 is approximately 1.5 A out of its binding site and there is no covalent bond between dUMP and the catalytic cysteine. Changes to partitioning among productive and non-productive conformations of reaction intermediates may contribute as much, if not more, to the diminished activity of this mutant than reduced stabilization of transition states.     

The structural mechanism for half-the-sites reactivity in an enzyme, thymidylate synthase, involves a relay of changes between subunits.

Thymidylate synthase (TS), a half-the-sites reactive enzyme, catalyzes the final step in the de novo biosynthesis of deoxythymidine monophosphate, dTMP, required for DNA replication. The cocrystal structure of TS from Pneumocystis carinii (PcTS), a new drug target for an important pathogen, with its substrate, deoxyuridine monophosphate (dUMP), and a cofactor mimic, CB3717, was determined. The structure, solved at 2.6 A resolution, shows an asymmetric dimer with two molecules of the substrate dUMP bound yet only one molecule of cofactor analogue bound. The structural evidence reveals that upon binding cofactor analogue and forming a covalent bond from the nucleophilic cysteine to the substrate, dUMP, at one active site, PcTS undergoes a conformational change that renders the opposite monomer incapable of forming a covalent bond or binding a molecule of cofactor analogue. The communication pathway between the two active sites is evident, allowing a structural definition of the basis of half-the-sites reactivity for thymidylate synthase and providing an example of such a mechanism for other half-the-sites reactive enzymes.     

Reversible dissociation and unfolding of the dimeric protein thymidylate synthase.

Conditions for in vitro unfolding and refolding of dimeric thymidylate synthase from Lactobacillus casei were found. Ultraviolet difference and circular dichroism spectra showed that the enzyme was completely unfolded at concentrations of urea over 5.5 M. As measured by restoration of enzyme activity, refolding was accomplished when 0.5 M potassium chloride was included in the refolding mixture. Recombination of subunits from catalytically inactive mutant homodimers to form an active hybrid dimer was achieved under these unfolding-refolding conditions, demonstrating a monomer to dimer association step.     

Interaction of pyridoxal phosphate with thymidylate synthase: Spectral and equilibrium dialysis studies

• 1.1. Changes in the spectrum of pyridoxal phosphate (PLP) were produced by adding an equimolar amount of native thymidylate synthase, but not by adding denatured enzyme or enzyme modified by sulfhydryl-blocking reagents.
• 2.2. The dissociation constant of the thymidylate synthase-PLP complex determined by equilibrium dialysis was 9 ± 1.6 μM, the maximum number of PLP molecules bound per molecule of native thymidylate synthase was 2.5 ± 0.4, and the Hill coefficient was 0.97.
• 3.3. No evidence of PLP binding was found with denatured thymidylate synthase, and only slight binding was observed when enzyme SH groups were blocked or when the active site was blocked with 5-fluorodeoxyuridylate (FdUMP) and methylenetetrahydrofoliate.
• 4.4. The presence of dUMP, dTMP, or FdUMP interfered with the binding of PLP to thymidylate synthase, and the presence of equimolar amounts of PLP interfered with the binding of dUMP.

     

Disruption of a salt bridge dramatically accelerates subunit exchange in duck delta2 crystallin

Intragenic complementation is a unique property of oligomeric enzymes with which to study subunit-subunit interactions. Complementation occurs when different subunits, each possessing distinct mutations that render the individual homomutant proteins inactive, interact to form a heteromutant protein with partial recovery of activity. In this paper, complementation events between human argininosuccinate lyase (ASL) and its homolog, duck delta2 crystallin, were characterized. Different active site mutants in delta2 crystallin complement by the regeneration of native-like active sites as reported previously for ASL. The complementarity of the ASL and delta2 crystallin subunit interfaces was illustrated by the in vivo formation of active hybrid tetramers from inactive ASL and inactive delta2 crystallin mutants. Subunits of both ASL and delta2 crystallin do not dissociate and reassociate in vitro at room temperature, even after 6 days of incubation, indicating that the multimerization interface is very strong. However, disruption of a salt bridge network in the tetrameric interface of delta2 crystallin caused a drastic acceleration of subunit dissociation. Double mutants combining these interface mutants with active site mutants of delta2 crystallin were able to dissociate and reassociate to form active tetramers in vitro within hours. These results suggest that exchange of subunits may occur without unfolding of the monomer. Intragenic complementation in these interface mutants occurs by reintroducing the native salt bridge interaction upon hetero-oligomerization. Our studies demonstrate the value of intragenic complementation as a tool for investigating subunit-subunit interactions in oligomeric proteins.     

Effects of ligand binding and conformational switching on intracellular stability of human thymidylate synthase

Thymidylate synthase (TS) is the target in colon cancer therapeutic protocols utilizing such drugs as 5-fluorouracil and raltitrexed. The effectiveness of these treatments is hampered by emerging drug resistance, usually related to increased levels of TS. Human TS (hTS) is unique among thymidylate synthases from all species examined as its loop 181-197 can assume two main conformations related by rotation of 180 degrees. In one conformation, "active", the catalytic Cys-195 is positioned in the active site; in the other conformation, "inactive", it is at the subunit interface. Also, in the active conformation, region 107-128 has one well-defined conformation while in the inactive conformation this region assumes multiple conformations and is disordered in crystals. The native protein exists in apparent equilibrium between the two conformational states, while the enzyme liganded with TS inhibitors assumes the active conformation. The native protein has been reported to bind to several mRNAs, including its own mRNA, but upon ligation, RNA binding activity is lost. Ligation of TS by inhibitors also stabilizes it to turnover. Since currently used TS-directed drugs stabilize the active conformation and slow down the enzyme degradation, it is postulated that inhibitors of hTS stabilizing the inactive conformation of hTS should cause a down-regulation in enzyme levels as well as inactivate the enzyme.     

Kinetic behaviour and allosteric regulation of human deoxycytidylate deaminase derived from leukemic cells

Deoxycytidylate deaminase has been highly purified (1232-fold) from human leukemia CCRF-CEM cells. The native molecular weight of the enzyme is 108 000 and subunit molecular weight 50 500, suggesting that the native enzyme exists as a dimer. The enzyme exhibits a sigmoidal initial velocity vs substrate concentration curve and is regulated by allosteric effectors, dCTP and TTP. The curve relating substrate concentration to initial velocity was changed from a sigmoidal shape to a hyperbolic one by the activator dCTP, while the inhibitor TTP increased the sigmoidicity of the curve. The molecular weight of deoxycytidylate deaminase was unchanged in the presence of allosteric effectors, indicating that aggregation-disaggregation is not the basis of regulation. Deoxycytidylate deaminase exhibited the greatest affinity for the substrate dCMP, with lesser affinity for ara-CMP, and least affinity for CMP. Ara-CMP was an effective substrate in the presence of dCTP concentrations exceeding 4 microM. These data indicate that human neoplastic cell deoxycytidylate deaminase is a highly regulated allosteric enzyme, which is likely to have a significant influence on cellular dUMP, dCTP and TTP pools. These findings further suggest, that the enzyme through its influence on dUMP levels is likely to modulate the biochemical effects of pyrimidine antimetabolites active against the thymidylate synthetase reaction and in the presence of elevated dCTP pools will promote deamination of ara-CMP to the inactive ara-UMP.     

Insights into folate/FAD-dependent tRNA methyltransferase mechanism: role of two highly conserved cysteines in catalysis

The flavoprotein TrmFO methylates specifically the C5 carbon of the highly conserved uridine 54 in tRNAs. Contrary to most methyltransferases, the 1-carbon unit transferred by TrmFO derives from 5,10-methylenetetrahydrofolate and not from S-adenosyl-L-methionine. The enzyme also employs the FAD hydroquinone as a reducing agent of the C5 methylene U54-tRNA intermediate in vitro. By analogy with the catalytic mechanism of thymidylate synthase ThyA, a conserved cysteine located near the FAD isoalloxazine ring was proposed to act as a nucleophile during catalysis. Here, we mutated this residue (Cys-53 in Bacillus subtilis TrmFO) to alanine and investigated its functional role. Biophysical characterization of this variant demonstrated the major structural role of Cys-53 in maintaining both the integrity and plasticity of the flavin binding site. Unexpectedly, gel mobility shift assays showed that, like the wild-type enzyme, the inactive C53A variant was capable of forming a covalent complex with a 5-fluorouridine-containing mini-RNA. This result confirms the existence of a covalent intermediate during catalysis but rules out a nucleophilic role for Cys-53. To identify the actual nucleophile, two other strictly conserved cysteines (Cys-192 and Cys-226) that are relatively far from the active site were replaced with alanine, and a double mutant C53A/C226A was generated. Interestingly, only mutations that target Cys-226 impeded TrmFO from forming a covalent complex and methylating tRNA. Altogether, we propose a revised mechanism for the m(5)U54 modification catalyzed by TrmFO, where Cys-226 attacks the C6 atom of the uridine, and Cys-53 plays the role of the general base abstracting the C5 proton.     

Importance of domain closure for the catalysis and regulation of Escherichia coli aspartate transcarbamoylase

Two hybrid versions of Escherichia coli aspartate transcarbamoylase were studied to determine the influence of domain closure on the homotropic and heterotropic properties of the enzyme. Each hybrid holoenzyme had one wild-type and one inactive catalytic subunit. In the first case the inactive catalytic subunit had Arg-54 replaced by alanine. The holoenzyme with this mutation in all six catalytic chains exhibits a 17,000-fold reduction in activity, no loss in substrate affinity, and an R state structurally identical to that of the wild-type enzyme. In the second case, the inactive catalytic subunit had Arg-105 replaced by alanine. The holoenzyme with this mutation in all six catalytic chains exhibits a 1,100-fold reduction in activity, substantial loss in substrate affinity, and loss of the ability to be converted to the R state. Thus, the R54A substitution results in a holoenzyme that can undergo closure of the catalytic chain domains to form the high activity, high affinity active site and to undergo the allosteric transition, whereas the R105A substitution results in a holoenzyme that can neither undergo domain closure nor the allosteric transition. The hybrid holoenzyme with one wild-type and one R54A catalytic subunit exhibited the same maximal velocity per active site as the wild-type holoenzyme, reduced cooperativity, and normal heterotropic interactions. The hybrid with one wild-type and one R105A catalytic subunit exhibited significantly reduced maximal velocity per active site as compared with the wild-type holoenzyme, reduced cooperativity, and substantially reduced heterotropic interactions. Small angle x-ray scattered was used to verify that the R105A-containing hybrid could attain an R state structure. These results indicate the global nature of the conformational changes associated with the allosteric transition in the enzyme. If one catalytic subunit cannot undergo domain closure to create the active sites, then the entire molecule cannot attain the high activity, high activity R state.