Thymidylate synthase with a C-terminal deletion catalyzes partial reactions but is unable to catalyze thymidylate formation.

The V316Am mutant of Lactobacillus casei thymidylate synthase has a single amino acid deletion at the C-terminus which abolishes catalysis of dTMP formation. However, V316Am catalyzes two partial reactions which require covalent catalysis: a CH2H4folate-dependent exchange of the 5-hydrogen of dUMP for protons in water and a thiol-dependent dehalogenation of 5-bromo- and 5-iodo-dUMP. These reactions proceed with kcat and Km values similar to those of the wild-type TS-catalyzed reactions. dUMP, dTMP, and FdUMP are competitive inhibitors of the debromination reaction with Ki values similar to those obtained with wild-type enzyme. These results show that removal of the terminal valine does not alter the ability of the enzyme to bind to or form covalent bonds with nucleotide ligands. V316Am also forms a covalent ternary complex with FdUMP and CH2H4folate. However, the affinity of the TS-FdUMP complex for the cofactor is reduced, and the rate of covalent ternary complex formation and its stability are significantly lower than with wild-type TS. These results allow us to place the major defects of the mutation on steps that occur subsequent to initial CH2H4folate binding.     

Catalytic mechanism of Chlamydia trachomatis flavin-dependent thymidylate synthase

Here we report on a Chlamydia trachomatis gene that complements the growth defect of a thymidylate synthase-deficient strain of Escherichia coli. The complementing gene encodes a 60.9-kDa protein that shows low level primary sequence homology to a new class of thymidylate-synthesizing enzymes, termed flavin-dependent thymidylate synthases (FDTS). Purified recombinant chlamydial FDTS (CTThyX) contains bound flavin. Results with site-directed mutants indicate that highly conserved arginine residues are required for flavin binding. Kinetic characterization indicates that CTThyX is active as a tetramer with NADPH, methylenetetrahydrofolate, and dUMP required as substrates, serving as source of reducing equivalents, methyl donor, and methyl acceptor, respectively. dTMP and H(4)folate are products of the reaction. Production of H(4)folate rather than H(2)folate, as in the classical thymidylate synthase reaction, eliminates the need for dihydrofolate reductase, explaining the trimethoprim-resistant phenotype displayed by thyA(-) E. coli-expressing CTThyX. In contrast to the extensively characterized thyA-encoded thymidylate synthases, which form a ternary complex with substrates dUMP and CH(2)H(4)folate and follow an ordered sequential mechanism, CTThyX follows a ping-pong kinetic mechanism involving a methyl enzyme intermediate. Mass spectrometry was used to localize the methyl group to a highly conserved arginine, and site-directed mutagenesis showed this arginine to be critical for thymidylate synthesizing activity. These differentiating characteristics clearly distinguish FDTS from ThyA, making this class of enzymes attractive targets for rational drug design.     

Mutation of asparagine 229 to aspartate in thymidylate synthase converts the enzyme to a deoxycytidylate methylase.

The conserved Asn 229 of thymidylate synthase (TS) forms a cyclic hydrogen bond network with the 3-NH and 4-O of the nucleotide substrate dUMP. The Asn 229 to Asp mutant of Lactobacillus casei thymidylate synthase (TS N229D) has been prepared, purified, and investigated. Steady-state kinetic parameters of TS N229D show 3.5- and 10-fold increases in the Km values of CH2H4folate and dUMP, respectively, and a 1000-fold decrease in kcat. Most important, the Asp 229 mutation changes the substrate specificity of TS to an enzyme which recognizes and methylates dCMP in preference to dUMP. With TS N229D the Km for dCMP is bout 3-fold higher than for dUMP, and the Km for CH2H4folate is increased about 5-fold; however, the kcat for dCMP methylation is 120-fold higher than that for dUMP methylation. Specificity for dCMP versus dUMP, as measured by kcat/Km, changes from negligible with wild-type TS to about a 40-fold increase with TS N229D. TS N229D reacts with CH2H4folate and FdUMP or FdCMP to form ternary complexes which are analogous to the TS-FdUMP-CH2H4folate complex. From what is known of the mechanism and structure of TS, the dramatic change in substrate specificity of TS N229D is proposed to involve a hydrogen bond network between Asp 229 and the 3-N and 4-NH2 of the cytosine heterocycle, causing protonation of the 3-N and stabilization of a reactive imino tautomer. A similar mechanism is proposed for related enzymes which catalyze one-carbon transfers to cytosine heterocycles.     

Trapping and partial characterization of an adduct postulated to be the covalent catalytic ternary complex of thymidylate synthase

The proposed mechanism of action of thymidylate synthase envisages the formation of a covalent ternary complex of the enzyme with the substrate dUMP and the cofactor 5,10-methylenetetrahydrofolate (CH2H4folate). The proposed structure of this adduct has been based by analogy on that of the covalent inhibitory ternary complex thymidylate synthase-FdUMP-CH2H4folate. Our recent success in using the protein precipitant trichloroacetic acid to trap the latter complex and covalent binary complexes of the enzyme with FdUMP, dUMP, and dTMP led to the use of this technique in attempts to trap the transient putative covalent catalytic ternary complex. Experiments performed with [2-14C]dUMP and [3',5',7,9-3H]CH2H4folate show that both the substrate and the cofactor remained bound to the protein after precipitation with trichloroacetic acid. The trapped putative covalent catalytic complex was subjected to CNBr fragmentation, and the resulting peptides were fractionated by reverse-phase high-pressure liquid chromatography. The isolated active site peptide was shown to retain the two ligands and was further characterized by a limited sequence analysis using the dansyl Edman procedure. The inhibitory ternary complex, which was formed with [14C]FdUMP and [3H]CH2H4folate, served as a control. The active site peptide isolated from the CNBr-treated inhibitory ternary complex was also subjected to sequence analysis. The two peptides exhibited identical sequences for the first four residues from the N-terminus, Ala-Leu-Pro-Pro, and the fifth amino acid residue was found to be associated with the labeled nucleotides and the cofactor.(ABSTRACT TRUNCATED AT 250 WORDS)     

A stable binary complex between Leishmania major thymidylate synthase and the substrate deoxyuridylate. A slow-binding interaction

The thymidylate synthase (TS) activity in Leishmania major resides on the bifunctional protein thymidylate synthase-dihydrofolate reductase (TS-DHFR). We have isolated, either by Sephadex G-25 chromatography or by nitrocellulose filter binding, a binary complex between the substrate deoxyuridylate (dUMP) and TS from L. major. The kinetics of binding support a "slow binding" mechanism in which dUMP initially binds to TS in a rapid, reversible pre-equilibrium step (Kd approximately 1 microM), followed by a slow first-order step (k = 3.5 X 10(-3) s-1) which results in the isolable complex; the rate constant for the dissociation of dUMP from this complex was 2.3 X 10(-4) s-1, and the overall dissociation constant was approximately 0.1 microM. The stoichiometry of dUMP to enzyme appears to be 1 mol of nucleotide bound/mol of dimeric TS-DHFR. Binary complexes between the stoichiometric inhibitor 5-fluorodeoxyuridylate (FdUMP) and TS, and between the product deoxythymidylate (dTMP) and TS were also isolated by nitrocellulose filter binding. Competition experiments indicated that each of these nucleotides were binding to the same site on the enzyme and that this site was the same as that occupied by the nucleotide in the FdUMP-cofactor X TS ternary complex. Thus, it appeared that the binary complexes were occupying the active site of TS. However, the preformed isolable dUMP X TS complex is neither on the catalytic path to dTMP nor did it inhibit TS activity, even though the dissociation of dUMP from this complex is several orders of magnitude slower than catalytic turnover (approximately 3 s-1). The results suggest that dUMP binds to one of the two subunits of the native protein in a catalytically incompetent form which does not inhibit activity of the other subunit.     

Kinetic studies on drug-resistant variants of Escherichia coli thymidylate synthase: functional effects of amino acid substitutions at residue 4.

A naturally occurring mutant of human thymidylate synthase (hTS) that contains a Tyr to His mutation at residue 33 was found to confer 4-fold resistance to 5-fluoro-2'-deoxyuridine (FdUrd), a prodrug of 5-fluoro-2'-deoxyuridine 5'-monophosphate (FdUMP). The crystal structure of hTS implicated this Tyr residue in a drug resistance mechanistic role that may include both substrate binding and catalysis (Schiffer et al., Biochemistry, 34, 16279-16287, 1995). Because of the existence of a defined kinetic scheme and the development of a bacterial expression vector for the overproduction of Escherichia coli TS (ecTS), we chose to initially study the corresponding residue in the bacterial enzyme, Tyr 4 of ecTS. Nine mutant ecTS enzymes that differed in sequence at position 4 were generated. Mutants with a charged or polar side chain (Ser, Cys, Asp, and Arg) and Gly precipitated in the cell paste, resulting in no catalytic activity in cell-free extracts. Although most of the His 4 mutant precipitated, sufficient amounts remained in the cell-free extract to permit isolation to near homogeneity. Wild-type ecTS and mutants with a hydrophobic side chain (Phe, Ile, and Val) were expressed at nearly 30% of the total cellular protein. The k(cat) values for the isolatable mutants were 2- to 10-fold lower than that of the wild-type enzyme, while the K(m) values for 2'-deoxyuridylate (dUMP) and 5,10-methylenetetrahydrofolate (CH(2)H(4)folate) were similar for all the mutants. Dissociation constants for binary complex formation determined by stopped-flow spectroscopy were similar for the wild-type and mutant enzymes for both dUMP and 2'-deoxythymidylate, indicating that this mutation does not significantly alter the binding of the natural nucleotide ligands. However, each mutant enzyme had three- to 5-fold lower affinity for FdUMP in the binary complex compared with the wild-type enzyme, and only His 4 showed a lower affinity for FdUMP in the ternary complex. Analysis of k(burst) showed that the initial binding of CH(2)H(4)folate is weaker for each mutant compared to the wild-type enzyme and that lower k(cat) values were due to compromised rates that govern the chemical transformation of bound substrates to bound products.     

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.     

Mechanism-based inactivation of thymidylate synthase by 5-(3-fluoropropyn-1-yl)-2'-deoxyuridine 5'-phosphate

5-Fluoropropynyl-2'-deoxyuridine 5'-phosphate (3) was designed as a mechanism-based inactivator of thymidylate synthase (TS). The inhibitor was synthesized from 5-iodo-2'-deoxyuridine and propargyl alcohol by palladium-catalyzed coupling, followed by fluorination and selective phosphorylation. Incubation of TS with 3, in the presence or absence of the CH2H4folate cofactor, caused rapid, irreversible inactivation of the enzyme.     

Characteristics of thymidylate synthase purified from a human colon adenocarcinoma

Thymidylate synthase has been purified greater than 4000-fold from a human colon adenocarcinoma maintained as a xenograft in immune-deprived mice. In this disease, the enzyme is an important target for the cytotoxic action of 5-fluorouracil, which is influenced by the reduced folate substrate CH2-H4PteGlu. Due to the importance of this interaction, and the existence in cells of folate species as polyglutamyl forms, the interaction of folylpolyglutamates with thymidylate synthase was examined. Polyglutamates of PteGlu were used as inhibitors, and the interaction of CH2-H4PteGlu polyglutamates as substrates or in an inhibitory ternary complex were also examined. Using PteGlu1-7, Ki values were determined. A maximal 125-fold decrease in Ki was observed between PteGlu1 and PteGlu4; further addition of up to three glutamyl residues did not result in an additional decrease in Ki. Despite the increased binding affinity of folypolyglutamates for this enzyme, no change in the Km values for either dUMP (3.6 microM) or CH2-H4PteGlu (4.3 microM) were detected when polyglutamates of [6R]CH2-H4PteGlu were used as substrates. Product inhibition studies demonstrated competitive inhibition between dTMP and dUMP in the presence of CH2-H4PteGlu5. In addition, CH2-H4PteGlu4 stabilized an inhibitory ternary complex formed between FdUMP, thymidylate synthase, and CH2-H4PteGlu4. Thus the data do not support a change in the order of substrate binding and product release upon polyglutamylation of CH2-H4PteGlu reported for non-human mammalian enzyme. This is the first study to characterize kinetically thymidylate synthase from a human colon adenocarcinoma.     

Subunit complementation of thymidylate synthase.

Each of the two active sites of thymidylate synthase contains amino acid residues contributed by the other subunit. For example, Arg-178 of one monomer binds the phosphate group of the substrate dUMP in the active site of the other monomer [Hardy et al. (1987) Science 235, 448-455]. Inactive mutants of such residues should combine with subunits of other inactive mutants to form heterodimeric hybrids with one functional active site. In vivo and in vitro approaches were used to test this hypothesis. In vivo complementation was accomplished by cotransforming plasmid mixtures encoding pools of inactive Arg-178 mutants and pools of inactive Cys-198 mutants into a host strain deficient in thymidylate synthase. Individual inactive mutants of Arg-178 were also cotransformed with the C198A mutant. Subunit complementation was detected by selection or screening for transformants which grew in the absence of thymidine, and hence produced active enzyme. Many mutants at each position representing a wide variety of size and charge supported subunit complementation. In vitro complementation was accomplished by reversible dissociation and unfolding of mixtures of purified individual inactive Arg-178 and Cys-198 mutant proteins. With the R178F + C198A heterodimer, the Km values for dUMP and CH2H4folate were similar to those of the wild-type enzyme. By titrating C198A with R178F under unfolding-refolding conditions, we were able to calculate the kcat value for the active heterodimer. The catalytic efficiency of the single wild-type active site of the C198A + R178F heterodimer approaches that of the wild-type enzyme.     

Thymidylate synthetase catalyzed exchange of tritiumfrom [5-3H]-2'-deoxyuridylate for protons of water.

Thymidylate synthetase catalyzes an exchange of tritium of [5-3H]dUMP for protons of water in the absence of CH2-H4folate. The turnover number for this reaction is some 45,000-fold lower than that of dTMP formation and Km is 1.2 X 10(-5) M, similar to the dissociation constant of the enzyme-dUMP complex determined by equilibrium dialysis. The presence of 4 mM folate has no effect on Vmax but results in a decrease in the Km of dUMP to a value close to that in the normal enzymic reaction. The exchange reaction provides definitive evidence that the enzymic reaction involves attack of a nucleophile of the enzyme on the 6 position of dUMP to provide a 5,6-dihydro-dUMP intermediate which is covalently bound to the enzyme. Stereochemical considerations of the exchange reaction require proposal of a partial reaction which is not completely sterospecific or a complex reaction in which protons of water are handled with complete stereospecificity in a fashion similar to the one carbon unit of the normal enzymic reaction.     

Spectroscopic studies of ternary complexes of thymidylate synthetase, deoxyribonucleotides, and folate analogs

Conformational changes accompanying the formation of binary and tightly bound ternary complexes of thymidylate synthetase and all possible combinations of three folate analogs (N-10-ethyl-quinazoline, folic acid triglutamate, and folic acid) and three deoxyribonucleotides (5-fluoro-2'-deoxyuridylic acid (FdUMP), 2'-deoxyuridylic acid (dUMP), and thymidylic acid (dTMP] were studied by means of ultraviolet difference spectroscopy. The amplitudes of the spectral changes upon ternary complex formation were 2-3-fold greater than those generated by formation of binary enzyme-nucleotide and enzyme-folate analog complexes. Difference spectra of the ternary complexes all showed a major increase in absorbance in the region of 320-340 nm, presumably due to perturbations of the folate analog chromophores, whereas decreases in absorbance occurred over a range of 260-310 nm. N-10-ethyl-quinazoline tended to form the complex with the greatest filtration efficiency on nitrocellulose filters, followed by folic acid triglutamate and folic acid, whereas among the nucleotides, the most stable complexes were formed with FdUMP, followed by dUMP and dTMP. A correlation was observed between the apparent stability of the ternary complex and the magnitude of the absorbance change in its difference spectrum. The formation of the various ternary complexes showed three different categories of rate behavior: 1) very rapid formation of the complex; 2) biphasic formation with a rapid phase and a slow phase requiring up to 90 min for completion; and 3) in the case of the ternary complex formed with enzyme, FdUMP, and folic acid, only a slow phase of binding. The slow formation of the latter complex was accompanied by concomitantly slow changes in the difference spectrum. However, in those cases of biphasic formation of the complexes, almost all of the spectral change occurred rapidly, and very little of it corresponded to the slow phase of complex formation. To accommodate these observations, a model is proposed involving a sequential interaction of the two subunits of thymidylate synthetase.     

Quinazoline folate analogs inhibit the catalytic activity of thymidylate synthase but allow binding of 5-fluorodeoxyuridylate

We have investigated some unusual aspects of the inhibition of mammalian thymidylate synthase (TS) by the folate antimetabolite, 10-propargyl-5,8-dideaza-folic acid (CB 3717). From our results, we conclude that binding of CB 3717 metabolites to one subunit of L1210 TS modified the conformation of the second active site of this enzyme so that it retained the ability to bind 5-fluro-2'-deoxyuridine-5'-monophosphate (FdUMP) but not its catalytic activity. Exposure of intact mouse L1210 cells to CB 3717 resulted in inactivation of cellular TS activity, yet desalted cytosol preparations from these cells retained the ability to bind FdUMP. The same effect was found with several analogs of CB 3717. Complexes of FdUMP formed in vitro with TS from cells exposed to CB 3717 were covalent and co-migrated on sodium dodecyl sulfate-polyacrylamide gel electrophoresis with complexes of FdUMP, folate cofactor, and TS from cells not exposed to CB 3717. In the presence of dUMP, a tightly bound complex rapidly formed between isolated pure TS and the pentaglutamate of CB 3717 but not the monoglutamate form of this compound. Binding experiments using CB 3717 pentaglutamate-inhibited TS suggested a stoichiometry of 1 mol of FdUMP bound per mol of dimeric TS.     

On the mechanism of 2'-deoxyuridylate hydroxymethylase

dUMP hydroxymethylase from SP01-infected Bacillus subtilis has been purified 160-fold by chromatography on DEAE-cellulose and ethylagarose. The enzyme catalyzes exchange of the 5-hydrogen of dUMP for protons of water in the presence or absence of the cofactor CH2-H4folate. Upon treatment with FdUMP and CH2-H4folate, an isolable covalent complex is formed which is believed to be structurally similar to a steady-state intermediate of the normal reaction. The FdUMP-CH2-H4folate-dUMP hydroxymethylase complex is stable toward denaturation with sodium dodecyl sulfate and shows a subunit molecular weight of 46 000. By analogy with chemical models and studies of dTMP synthetase, a mechanism is proposed for the reaction catalyzed by dUMP hydroxymethylase.     

Stereochemical mechanism of action for thymidylate synthase based on the X-ray structure of the covalent inhibitory ternary complex with 5-fluoro-2'-deoxyuridylate and 5,10-methylenetetrahydrofolate

The structure of the Escherichia coli thymidylate synthase (TS) covalent inhibitory ternary complex consisting of enzyme, 5-fluoro-2'-deoxyuridylate (FdUMP) and 5,10-methylene tetrahydrofolate (CH2-H4PteGlu) has been determined at 2.5 A resolution using difference Fourier methods. This complex is believed to be a stable structural analog of a true catalytic intermediate. Knowledge of its three-dimensional structure and that for the apo enzyme, also reported here, suggests for the first time how TS may activate dUMP and CH2-H4PteGlu leading to formation of the intermediate and offers additional support for the hypothesis that the substrate and cofactor are linked by a methylene bridge between C-5 of the substrate nucleotide and N-5 of the cofactor. By correlating these structural results with the known stereospecificity of the TS-catalyzed reaction it can be inferred that the catalytic intermediate, once formed, must undergo a conformational isomerization before eliminating across the bond linking C-5 of dUMP to C-11 of the cofactor. The elimination itself may be catalyzed by proton transfer to the cofactor's 5 nitrogen from invariant Asp169 buried deep in the TS active site. The juxtaposition of Asp169 and bound tetrahydrofolate in TS is remarkably reminiscent of binding geometry found in dihydrofolate reductase where a similarly conserved carboxyl group serves as a general acid for protonating the corresponding pyrazine ring nitrogen of dihydrofolate.     

Studies on the polyglutamate specificity of thymidylate synthase from fetal pig liver

Thymidylate synthase has been purified 1700-fold from fetal pig livers by using chromatography on Affigel-Blue, DEAE-52, and hydroxylapatite. Steady-state kinetic measurements indicate that catalysis proceeds via an ordered sequential mechanism. When 5,10-methylenetetrahydro-pteroylmonoglutamate (CH2-H4PteGlu1) is used as the substrate, dUMP is bound prior to CH2-H4PTeGlu1, and 7,8-dihydropteroylmonoglutamate (H2PteGlu1) is released prior to dTMP. Pteroylpolyglutamates (PteGlun) are inhibitors of thymidylate synthase activity and are competitive with respect to CH2-H4PteGlu1 and uncompetitive with respect to dUMP. Inhibition constants (Ki values), which correspond to dissociation constants for the dissociation of PteGlun from the enzyme-dUMP-PteGlun ternary complex, have been determined for PteGlun derivatives with one to seven glutamyl residues: PteGlu1, 10 microM; PteGlu2, 0.3 microM; PteGlu3, 0.2 microM; PteGlu4, 0.06 microM; PteGlu5, 0.10 microM; PteGlu6, 0.12 microM; PteGlu7, 0.15 microM. Thus, thymidylate synthase from fetal pig liver preferentially binds pteroylpolyglutamates with four glutamyl residues, but derivatives with two to seven glutamyl residues all bind at least 30-fold more tightly than the monoglutamate. When CH2-H4PteGlu4 is used as the one carbon donor for thymidylate biosynthesis, the order of substrate binding and product release is reversed, with binding of CH2-H4PteGlu4 preceding that of dUMP and release of dTMP preceding release of H2PteGlu4. Vmax and Km values for dUMP and CH2-H4PteGlun show relatively little change as the polyglutamate chain length of the substrate is varied.(ABSTRACT TRUNCATED AT 250 WORDS)     

Substitution at residue 214 of human thymidylate synthase alters nucleotide binding and isomerization of ligand-protein complexes

Based on crystal structures of bacterial thymidylate synthases (TS), a glutamine corresponding to residue 214 in human TS (hTS) is located in a region that is postulated to be critical for conformational changes that occur upon ligand binding. Previous steady-state kinetic studies indicated that replacement of glutamine at position 214 (Gln214) of hTS by other residues results in a decrease in nucleotide binding and catalysis, with only minor effects on folate binding (D. J. Steadman et al. (1998) Biochemistry 37, 7089-7095). The data suggested that Gln214 maintains the enzyme in a conformation that facilitates nucleotide binding. In the present study, transient-state kinetic analysis was utilized to determine rate constants that govern specific steps along the catalytic pathway of hTS, which provides the first detailed kinetic mechanism for hTS. Analysis of the reaction mechanisms of mutant TSs revealed that substitution at position 214 significantly affects nucleotide binding and the rate of chemical conversion of bound substrates to products, which is consistent with the results of steady-state kinetic analysis. Furthermore, it is shown that substitution at position 214 affects the rate of isomerization, presumably from an open to a closed form of the enzyme-substrate complex. Although the affinity of the initial binding of CH2H4folate is not substantially affected, Kiso, the ratio of the forward rate of isomerization (kiso) to the reverse rate of isomerization (kr, iso), is 2-6-fold lower for the mutants at position 214 compared to Q214, with the greatest effects on kiso. In addition, the binding of the folate analogue, CB3717, to dUMP binary complexes of mutant enzymes was characterized by a slow isomerization phase that was not detected in binding studies utilizing wild-type hTS. The data are consistent with the hypothesis that Gln214 is located at a structurally critical region of the enzyme.     

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.