High-level expression and rapid purification of tRNA (m5U54)-methyltransferase

We report an extremely high-level expression system for tRNA (m5U54)-methyltransferase (RUMT), and a purification strategy which routinely yields 20 to 50 mg of homogeneous RUMT per liter of Escherichia coli cells. The RUMT gene (trmA) was cloned into a pET vector and transformed into E. coli BL21 (DE3) cells. Following induction, this system produces active enzyme at a level approaching 50% of the total soluble protein. A purification scheme consisting of DEAE-cellulose chromatography to remove nucleic acids, followed by phosphocellulose chromatography, provides homogeneous enzyme. The entire procedure, from cell growth to purified enzyme, takes less than 2 days. This represents a significant improvement over the previously published expression/purification protocol for RUMT (Gu, X, and Santi, D.V., Protein Expression Purif. 2, 66-68, 1991), which typically nets 5- to 10-fold less enzyme per liter of cells and is substantially more labor intensive.

A C-terminal conformational equilibrium in thymidylate synthase observed by electron paramagnetic resonance spectroscopy

A spin-label was attached to the C-terminal side chain of Lactobacillus casei thymidylate synthase (TS, EC2.1.1.45), and EPR spectroscopy was used to study the change in conformational equilibrium that occurs when the enzyme binds nucleotides or the methylenetetrahydrofolate analog CB3717. The C244T/V316C mutant TS has only two cysteines, the active site Cys-198 and an engineered cysteine which replaces valine as the C-terminal residue. dUMP was used to block the active-site cysteine while the C-terminus was reacted with the spin-label 4-maleimido-2,2,6,6- tetramethylpiperidinyl-1-oxy. Exclusive attachment of the label to the C-terminal cysteine was verified by a study of the labeled enzyme's reaction with 5,5'-dithiobis(2-nitrobenzoic acid). EPR spectra of the labeled enzyme and its complexes were composed of two components corresponding to populations of both flexible and more immobilized forms of the C-terminus (tau C = 1 and 9.7 ns, respectively). Ligand binding increased the population of the more immobilized form of the C-terminus with the following series: free enzyme < E.dUMP approximately dTMP approximately E.FdUMP < E.CB3717 < E.dUMP.CB3717. Ligand-induced perturbation of the conformational equilibrium was titratable and indicated approximate Kd values of 3 and 13 microM for formation of the E.dUMP and E.CB3717 binary complexes, respectively, and 7 microM for the binding of CB3717 to the E.dUMP complex. Immobilization of the spin-label correlated well with crystallographic B-factors of the C-terminal residue in corresponding TS crystal structures. These results show that TS has two major conformations which are in equilibrium, and the position of the equilibrium changes in the presence of ligands.

In vitro methylation of Escherichia coli 16S rRNA by tRNA (m5U54)-methyltransferase

16S rRNA, isolated from Escherichia coli or synthesized in vitro, is methylated by tRNA (m5U54)-methyltransferase (RUMT) and S-adenosyl-L-methionine to give ribothymidine (m5U). By methylation studies of 16S rRNA fragments, nearest-neighbor analysis, and nuclease protection experiments, the site of methylation was identified as U788. We have previously shown that the substrate consensus sequence for the T-arm of tRNA consists of a 2-5 base-pair stem and a 7-base loop, with certain constraints on base substitutions within the loop, and in the first two bases which close the loop [Gu, X., & Santi, D. V. (1991) Biochemistry 30, 2999-3002]. U788 of 16S rRNA is within a 9-base loop of a predicted stem-loop structure of 16S rRNA. If Ado substitution is allowed at the third and seventh positions of the loop and the first and ninth bases of the loop form an A-C base pair, the resulting stem-loop falls within the RUMT consensus sequence of the T-arm of tRNA. Individual mutants of the tRNA T-arm at these positions confirm that the substitutions are allowable, and expand the previous consensus sequence. Further, prevention of 7-base loop formation by requiring C-C base-pair formation at the loop closure abolishes substrate activity. RUMT forms a complex with Syn 16S rRNA which can be isolated on nitrocellulose filters or by SDS-PAGE electrophoresis. The enzyme also catalyzes exchange of tritium of [3H]Ura-16S rRNA for protons of water. By analogy with studies with tRNA [Gu, X., & Santi, D. V. (1991) Biochemistry 31, 10295-10302], the mechanism of methylation is proposed to involve formation of a covalent, albeit reversible, Michael adduct with the target U788 of 16S rRNA.

Thermal stabilization of thymidylate synthase by engineering two disulfide bridges across the dimer interface

Thermal inactivation of oligomeric enzymes is most often irreversible and is frequently accompanied by precipitation. We have engineered two symmetry related disulfide bridges (155-188' and 188-155') across the subunit interface of Lactobacillus casei thymidylate synthase, at sites chosen on the basis of an algorithm for the introduction of stereochemically unstrained bridges into proteins. In this communication, we demonstrate a remarkable enhancement in the thermal stability of the covalently cross-linked double disulfide containing dimeric enzyme. The mutant enzyme remains soluble and retains secondary structure even at 90 degrees C, in contrast to the wild-type enzyme which precipitates at 52 degrees C. Furthermore, the mutant enzyme has a temperature optimum of 55 degrees C and possesses appreciable enzymatic activity at 65 degrees C. Cooling restores complete activity, in the mutant protein, demonstrating reversible thermal unfolding. The results suggest that inter-subunit crosslinks can impart appreciable thermal stability in multimeric enzymes.

Enzymatic mechanism of tRNA (m5U54)methyltransferase

tRNA (m5U54)methyltransferase (RUMT) catalyzes the methylation of uridine 54 of transfer RNA by S-adenosyl-L-methionine. In this report, we present the enzymatic mechanism of RUMT, including the stereochemical course of the methylation reaction, and discuss RUMT-tRNA recognition. As part of its enzymatic mechanism, we postulate that RUMT catalyzes the disruption of RNA-RNA contacts. We also show that many nucleotide substitutions can be made in the T-loop of tRNA without affecting RUMT binding, indicating that the recognition of the T-loop by RUMT is not stringent.

Interaction of thymidylate synthase with pyridoxal 5'-phosphate as studied by UV/visible difference spectroscopy and molecular modeling

Pyridoxal 5'-phosphate (PLP) is an effective inhibitor of Lactobacillus casei thymidylate synthase (TS), competitive with respect to the nucleotide substrate dUMP (Chen et al., 1989). The UV/vis difference spectra of TS-PLP complexes show lambda max at 328 nm due to the specific interaction between Cys 198 of TS and PLP to form a thiohemiacetal, and lambda min at 388 nm due to depletion of free PLP. At high concentrations of PLP a new absorbance at 430 nm forms due to nonspecific Schiff base formation between PLP and lysine residues of the enzyme. Using spectral titration at 328 nm, the binding constant of the specific TS-PLP complex was determined to be 0.5 microM, and the stoichiometry was 2 mol of PLP/mol of TS dimer. The 328-nm absorbance of the TS-PLP complex can be competitively and completely eliminated by addition of dUMP or dTMP; this serves as a convenient binding assay for molecules which bind to the active site of TS. Analogs of PLP which do not contain the phosphate or the aldehyde moieties of PLP bound poorly to the enzyme, thus demonstrating the importance of these functional groups for binding. When treated with PLP, C244T TS, which contains the active site Cys 198 as the sole cysteine residue, showed the same properties as the wild-type enzyme. Treatment of the C198A and C198S mutants with PLP did not produce the absorbance at 328 nm assigned to thiohemiacetal formation.(ABSTRACT TRUNCATED AT 250 WORDS)

The dihydrofolate reductase domain of Plasmodium falciparum thymidylate synthase-dihydrofolate reductase. Gene synthesis, expression, and anti-folate-resistant mutants

A 693-base pair gene coding for the 27,132-dalton dihydrofolate reductase (DHFR) domain of the thymidylate synthase-dihydrofolate reductase (TS-DHFR) bifunctional protein of Plasmodium falciparum was designed to have Escherichia coli codon preference and multiple unique restriction sites and was chemically synthesized. The gene was overexpressed (> 50% total cellular protein) in E. coli as insoluble inclusion bodies which could be unfolded and refolded to recover soluble enzyme activity. The refolded DHFR was purified by methotrexate-Sepharose affinity chromatography to give the homogeneous enzyme. Active site titration with methotrexate revealed that the purified protein was fully active. The purified DHFR migrates as a single band on sodium dodecyl sulfate-polyacrylamide gel electrophoresis with apparent mass of approximately 30 kDa, and gel filtration showed that the protein is a monomer. The yield of purified enzyme was about 5-6 mg/liter of bacterial culture. Kinetic properties of the purified recombinant DHFR were similar to those reported for wild type bifunctional TS-DHFR. Cassette mutagenesis of the synthetic gene was performed to give the S108N and the N51I + S108N mutants which provided DHFRs analogous to pyrimethamine-resistant mutants found in nature.

Catalytically active cross-species heterodimers of thymidylate synthase

Thymidylate synthase (TS) is a highly conserved homodimeric enzyme with two active sites, each of which contains amino acid residues from both subunits. We show that the conservation at the subunit interface between Escherichia coli TS and Lactobacillus casei TS is sufficient to permit the formation of a cross-species heterodimer between subunits of E. coli TS and L. casei TS. Heterodimer formation was monitored by the generation of catalytic activity when combinations of inactive E. coli homodimers and inactive L. casei homodimers were mixed under conditions of reversible unfolding and dissociation. The inactive L. casei mutant enzymes (Lc)C198A, (Lc)C198L, and (Lc)V316Am were tested as Arg donors to the active sites of the inactive E. coli mutant enzymes (Ec)R126Q and (Ec)R126E, while the inactive E. coli mutant enzymes (Ec)K48Q, (Ec)C146S, (Ec)R166Q, and (Ec)I264Am were tested as Arg donors to the active site of inactive (Lc)R178F. Except for (Lc)V316Am, all of the mutant enzymes tested were able to form catalytically active cross-species heterodimers. (Lc)C198A and (Ec)R126Q were cotransformed on compatible plasmids into a thymine-requiring E. coli host, and this combination was able to form sufficient active TS in vivo to support growth. Titration of (Ec)R126Q with (Lc)C198A showed that the cross-species heterodimer formed with the same probability as the intraspecies homodimers in the refolding mixture. The single active site formed by this pair has kcat and Km values similar to those of an intraspecies heterodimer.

Asparagine 229 in thymidylate synthase contributes to, but is not essential for, catalysis

The conserved Asn-229 (N229) of thymidylate synthase (TS, EC 2.1.1.45) provides the only side chain that directly hydrogen bonds with the pyrimidine ring of the substrate dUMP. The carboxamide moiety forms a cyclic hydrogen bond network with the NH-3 and O-4 of the base and is a prime candidate for assisting proton-transfer reactions that occur at O-4 of the pyrimidine ring of dUMP. A complete replacement set of mutants at position 229 of Lactobacillus casei TS (N229 mutants) has been prepared, purified, and characterized. Fifteen of the 19 TS mutants were catalytically active. Steady-state kinetic parameters of N229 mutants varied 17- and 115-fold in the Km values for 5,10-methylene-5,6,7,8-tetrahydrofolate and dUMP, respectively, 1000-fold in kcat values, and 10,000-fold in kcat/Km values. Wild-type TS possesses lower Km and higher kcat and kcat/Km values than any of the TS N229 mutants. We conclude that N229 contributes to, but is not essential for, binding and catalysis. When the wild-type enzyme was not considered, there were excellent correlations between log kcat and the hydrophobicity of the side chains at position 229, in which the more hydrophobic side chains showed higher values. Our results suggest a unique interaction between N229 and the substrates that seems important in appropriately positioning the uracil heterocycle for catalysis. We propose that in the absence of N229, the electrophilic catalyst that transfers protons to the O-4 and stabilizes enol intermediates is a highly conserved molecule of water.

Exclusion of 2'-deoxycytidine 5'-monophosphate by asparagine 229 of thymidylate synthase

In thymidylate synthase (TS, EC 2.1.1.45), the only side chain in direct hydrogen bonding with the pyrimidine ring of the substrate dUMP is asparagine 229 (N229). In binary and ternary complexes, the carboxamide moiety of the side chain of N229 forms a cyclic hydrogen bond network bridging N-3 and O-4 of the uracil heterocycle. Most of the N229 mutants of TS bind dUMP and catalyze dTMP formation as well as the wild-type enzyme; thus, N229 does not contribute to binding of dUMP. Wild-type TS binds dCMP weakly and does not accept dCMP as a substrate. Mutations at N229 of TS modify the interaction of TS with dCMP. TS N229D and TS N229E catalyze the methylation of dCMP [Liu, L., & Santi, D. V. (1992) Biochemistry 31, 5010-5014]. With the exception of the TS N229Q, most of the N229 mutants bind dCMP as well as or tighter than dUMP and bind dCMP 300-3000-fold tighter than wild-type TS. We conclude that TS discriminates binding of dUMP versus dCMP by a 3-4 kcal mol-1 difference in binding energy by exclusion of dCMP from the active site. We propose that this exclusion is a consequence of untoward interactions between dCMP and the side-chain carboxamide group of the Asn or Gln at position 229 of TS. We speculate that exclusion of cytosine versus uracil by Asn or Gln may account for specificity observed in other protein-pyrimidine interactions.

Dihydrofolate reductase from the pathogenic fungus Pneumocystis carinii: catalytic properties and interaction with antifolates

Dihydrofolate reductase (DHFR) from the fungus Pneumocystis carinii (pcDHFR), a target for antifolate inhibitors, has been compared with host enzyme, human DHFR (hDHFR), and with DHFR from Escherichia coli. Among the results of the considerable structural differences between pcDHFR and the other two enzymes is a much higher turnover number (kcat, 136 s-1) for pcDHFR. This is due to rapid hydride transfer from NADPH to dihydrofolate (rate constant 402 s-1), very rapid dissociation of NADP from the product complex (rate constant, k(off), > 1000 s-1), and after NADPH binding, rapid dissociation of tetrahydrofolate (k(off), 216 s-1). Cycling of pcDHFR is almost exclusively by this pathway. The high kcat contributes to a high Km for NADPH (9 microM) and an unusually high Km for dihydrofolate (2.5 microM). Nevertheless, the efficiency of pcDHFR is greater than DHFR from E. coli and about 25% that of hDHFR. Of seven clinically relevant inhibitors investigated, only one (trimethoprim) had a slightly lower Ki for pcDHFR than for hDHFR. The therapeutic value of trimethoprim-sulfa treatment of P. carinii infections indicates that other factors play an important role, but the results are consistent with the frequency of complications due to toxicity of trimethoprim.

Refined structures of substrate-bound and phosphate-bound thymidylate synthase from Lactobacillus casei

Crystal structures of two crystal forms of the complex of Lactobacillus casei (TS) with its substrate dUMP have been solved and refined at 2.55 A resolution. The two crystal forms differ by approximately 5% in the c-axis length. The TS-dUMP complexes are symmetric dimers with dUMP bound equivalently in both active sites. dUMP is non-covalently bound in the same conformation as in ternary complexes of TS with dUMP and cofactor or cofactor analogs. The same hydrogen bonds are made between TS and substrate in the binary and ternary complexes. We have also determined the 2.36 A crystal structure of phosphate-bound L. casei TS. This structure has been refined to an R-factor of 19.3% with highly constrained geometry. Refinement has revealed the locations of all residues in the protein, including the disordered residues 90 to 119, which are part of an insert found only in the L. casei and Staphylococcus aureus transposon Tn4003 TS sequences. The 2.9 A multiple isomorphous replacement (MIR) structure of L. casei TS in a complex with its substrate dUMP has been refined to a crystallographic R-factor of 15.5%. Reducing agents were withheld from crystallization solutions during MIR structure determination to allow heavy-metal labeling of the cysteine residues. Therefore, the active-site cysteine residue in this structure is oxidized and the dUMP is found at half-occupancy in the active site. No significant conformational difference was found between the phosphate-bound and dUMP-bound structures. The TS-dUMP structures were better ordered than the phosphate-bound TS or the oxidized TS-dUMP, particularly Arg23, which is clearly hydrogen-bonded to the phosphate group of dUMP. A large and a small P6(1)22 crystal form are observed for both phosphate-bound and dUMP-bound L. casei TS. The small cell forms of the phosphate-bound and dUMP-bound enzyme are isomorphous, whereas the cell constants of the larger cell form change slightly when dUMP is bound (c = 240 A versus c = 243 A). For both liganded and unliganded enzyme, conversion from the small to the large crystal form sometimes occurs spontaneously, and the crystal packing changes at a single interface. Conversion may be the result of a small change in pH in the mother liquor surrounding the crystal. A single intermolecular contact between symmetry-related Asp287 residues is disrupted on going from the small to the large crystal form.

Structures of thymidylate synthase with a C-terminal deletion: role of the C-terminus in alignment of 2'-deoxyuridine 5'-monophosphate and 5,10-methylenetetrahydrofolate

Thymidylate synthase undergoes a major conformational change upon ligand binding, where the carboxyl terminus displays the largest movement (approximately 4 A). This movement from an "open" unliganded state to the "closed" complexed conformation plays a crucial role in the correct orientation of substrates and in product formation. The mutant lacking the C-terminal valine (V316Am) of the enzyme is inactive. X-ray crystal structures of V316Am and its complexes with dUMP, FdUMP, and both FdUMP and CH2H4folate are described. The structures show that ligands are bound within the active site, but in different modes than those in analogous, wild-type thymidylate synthase structures. The 2.7-A binary complex structures of V316Am with FdUMP and dUMP show that the pyrimidine and ribose moieties of the nucleotides are pivoted approximately 20 degrees around the 3'-hydroxyl compared to dUMP in the wild-type enzyme. The 2.7-A crystal structure of V316Am complexed with cofactor, CH2H4folate, and the substrate analog, FdUMP, shows these ligands bound in an open conformation similar to that of the unliganded enzyme. In this ternary complex, the imidazolidine ring of the cofactor is open and has reacted with water to form 5-HOCH2H4folate. 5-HOCH2H4folate is structural evidence for the 5-iminium ion intermediate, which is the proposed reactive form of CH2H4folate. The altered ligand binding modes observed in the three V316Am complex structures open new venues for the design of novel TS inhibitors.

Cloning, expression, and characterization of Cryptococcus neoformans dihydrofolate reductase

The Cryptococcus neoformans dihydrofolate reductase (DHFR) gene has been isolated from cDNA and genomic DNA libraries. The 690-base pair coding sequence codes for a 25,152-Da protein, which is the largest monofunctional DHFR yet reported. The gene contains two introns, and several putative regulatory sequences have been identified. The coding sequence was placed in a pUC-based expression vector, which expresses C. neoformans DHFR in Escherichia coli at a level of about 5% of the total soluble extract. The expressed DHFR was purified to homogeneity by methotrexate-Sepharose affinity chromatography, followed by anion exchange chromatography on Q-Sepharose. On SDS-polyacrylamide gel electrophoresis, the purified enzyme migrates as a single protein with apparent mass of 28 kDa. The molecular weight, as determined by electrospray mass spectral analysis, and the amino-terminal sequence are in accord with what was predicted from the DNA sequence. Steady state kinetic parameters, effects of pH, salts, and inhibition constants of several anti-folates have been determined.

Structure-based discovery of inhibitors of thymidylate synthase

A molecular docking computer program (DOCK) was used to screen the Fine Chemical Directory, a database of commercially available compounds, for molecules that are complementary to thymidylate synthase (TS), a chemotherapeutic target. Besides retrieving the substrate and several known inhibitors, DOCK proposed putative inhibitors previously unknown to bind to the enzyme. Three of these compounds inhibited Lactobacillus casei TS at submillimolar concentrations. One of these inhibitors, sulisobenzone, crystallized with TS in two configurations that differed from the DOCK-favored geometry: a counterion was bound in the substrate site, which resulted in a 6 to 9 angstrom displacement of the inhibitor. The structure of the complexes suggested another binding region in the active site that could be exploited. This region was probed with molecules sterically similar to sulisobenzone, which led to the identification of a family of phenolphthalein analogs that inhibit TS in the 1 to 30 micromolar range. These inhibitors do not resemble the substrates of the enzyme. A crystal structure of phenolphthalein with TS shows that it binds in the target site in a configuration that resembles the one suggested by DOCK.

Covalent adducts between tRNA (m5U54)-methyltransferase and RNA substrates

The interaction of tRNA (m5U54)-methyltransferase (RUMT) with in vitro synthesized unmodified tRNA and a 17-base oligoribonucleotide analog of the T-arm of tRNA in the absence of AdoMet has been investigated. Binary complexes are formed which are isolable on nitrocellulose filters and are composed of noncovalent and covalent complexes in nearly equal amounts. The covalent RUMT-RNA complexes are stable to SDS-PAGE and migrate slower than free enzyme or RNA. Kinetic and thermodynamic constants involved in formation and disruption of noncovalent and covalent binary complexes have been determined and interpreted in the context of steady-state kinetic parameters of the enzyme-catalyzed methylation and 5-H exchange of substrate. The results show that the isolable covalent complex is kinetically incompetent as an intermediate for methylation. Isotope trapping experiments show that when AdoMet is added to preformed binary complex, all bound tRNA is converted to methylated product; thus, the covalent complexes are chemically competent to form products. We have concluded that, after a reversible binary complex is formed, the catalytic thiol adds to the 6-carbon of the U54 of tRNA. The initial adduct leaves the reaction pathway to protonation at carbon 5; the latter can deprotonate and re-enter the pathway to form methylated product. It is speculated that covalent binary RUMT-RNA adducts may serve as depots of enzyme-tRNA complexes primed for methylation, or in unknown roles with RNAs other than tRNA.

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.

Purification methods for recombinant Lactobacillus casei thymidylate synthase and mutants: a general, automated procedure

General procedures for the rapid, large-scale purification of recombinant Lactobacillus casei thymidylate synthase and its mutants have been established. An effective method employs sequential phosphocellulose and hydroxylapatite chromatography. Crude cell extracts are directly applied to phosphocellulose, and the enzyme is obtained in a nearly pure state by stepwise elution with KCl. The eluate is directly applied to hydroxylapatite, and the homogeneous enzyme is eluted with a gradient of potassium phosphate. The method has been successful for the purification of recombinant wild-type enzyme and all mutants thus far examined. The entire purification procedure has been automated using a commonly available FPLC system and can be performed in several hours with minimal operator time.

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.

Complete replacement set of amino acids at the C-terminus of thymidylate synthase: quantitative structure-activity relationship of mutants of an enzyme

The C-terminal residue of thymidylate synthase (TS) is highly conserved and has been implicated in cofactor binding, catalysis, and a conformational change. The codon for the C-terminal valine of Lactobacillus casei TS has been replaced with those for 19 other amino acids and the amber stop codon. Fourteen of the resulting mutant proteins were active by genetic complementation using a Thy- strain of Escherichia coli, and 18 mutants were active by in vitro assay. Only the aspartate and amber mutations had undetectable activity. All of the mutants were expressed at high levels (5-30% of soluble protein) and were purified by phosphocellulose chromatography. In general, the alterations at position 316 led to little effect on the Km for dUMP, an increase in Km for the folate cofactor, and a decrease in kcat. The observations show that TS can tolerate the substitution of most amino acids for valine at the C-terminus without a complete loss of activity, that hydrophobic substitutions are preferred, and that the C-terminal side chain is involved in both cofactor binding and catalysis. There was an excellent correlation between log kcat and hydrophobicity of the side chain at position 316 and an inverse correlation between log Km and the hydrophobicity of this residue. Kinetic parameters of the cofactor-independent TS-catalyzed dehalogenation of BrdUMP showed no variation with the side chain at position 316. In context of the structure of TS, it is proposed that binding of the cofactor triggers a conformational change in which the C-terminal side chain undergoes hydrophobic interactions that stabilize a rate-limiting transition state of the TS reaction.

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.

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.

Identification of highest-affinity ligands by affinity selection from equimolar peptide mixtures generated by robotic synthesis

A fully automated peptide synthesizer has been constructed that is capable of the simultaneous synthesis of up to 36 individual peptides and the synthesis of equimolar peptide mixtures. The instrument consists of an array of reaction vessels, a series of solenoid valves to control liquid flow, and a Zymark robot to deliver solvents and reagents; all components are computer controlled and coordinated. Equimolar peptide mixtures are obtained by algorithms that automate the mixing and distribution of peptide-resin particles. This technology was used to synthesize a library of 361 peptides, generated by randomizing two critical binding residues of a 10-mer epitope known to bind an anti-human immuno-deficiency virus gp120 monoclonal antibody. Each critical residue was substituted with 19 amino acids consisting of all the natural amino acids except cysteine. The library was synthesized as 19 pools, each containing 19 peptides. Each pool was screened in a solution-phase competition ELISA assay. The 12 most inhibitory peptides in the library were isolated by a rapid affinity-selection method and were identified by mass spectrometry and amino acid analysis. The binding properties of these 12 selected peptides were verified by synthesis and assay of the individual peptides. The two critical residues investigated were found to contribute independently to antibody binding.

A rapid method for determination of endoproteinase substrate specificity: specificity of the 3C proteinase from hepatitis A virus

The preferred amino acid residues at the P'1 and P'2 positions of peptide substrates of the 3C proteinase from hepatitis A virus (HAV-3C) have been determined by a rapid screening method. The enzyme was presented with two separate mixtures of N-terminal acetylated peptides, which were identical in sequence except for the amino acids at the P'1 or P'2 positions, where a set of 15 or 16 amino acids was introduced. Enzyme-catalyzed hydrolysis of the peptide mixtures generated free amino termini, which allowed direct sequence analysis by Edman degradation. The relative yield of each amino acid product in the appropriate sequencing cycle gave the amount of each substrate mixture component hydrolyzed. This allowed the simultaneous evaluation of the relative kcat/Km values for each component in the mixture. The peptide substrates preferred by the HAV-3C proteinase in the P'1 mixture were glycine, alanine, and serine. The enzyme has little specificity at P'2; only arginine and proline peptides were excluded as substrates. This method provides a rapid determination of the preferred residues for a peptide substrate and should be applicable to other endoproteinases.