Aspartate 221 of thymidylate synthase is involved in folate cofactor binding and in catalysis

Structural studies indicate that Asp 221 of Lactobacilluscasei thymidylate synthase forms a hydrogen bond network with the 2-amino and 3-imino groups of the folate [Matthews, D. A. (1990) J. Mol. Biol. 214, 937-948; Finer-Moore, J. S. (1990)Biochemistry 29, 6977-6986] that has been proposed to participate in catalysis. We prepared a complete replacement set of 19 mutants at position 221 of L. casei thymidylate synthase. Of these, the only one with sufficient activity to complement growth of a thymidylate synthase-deficient host was the Cys mutant. To further elucidate the function of the Asp 221 side chain, seven thymidylate synthase 221 mutants were studied in detail with regard to catalysis of dTMP formation and of thymidylate synthase partial reactions. Most of the mutants bound the nucleotide substrate dUMP with only moderate loss of binding affinity, indicating that the Asp side chain does not contribute to dUMP binding. Most of the mutants catalyzed the cofactor-independent dehalogenation of 5-bromodUMP; hence, the Asp side chain of TS is not essential for addition of the catalytic Cys residue to the nucleotide substrate. Mutants showed decreased affinity for the folate cofactor, but those with side chains capable of hydrogen bond formation were less severely affected. Some of the mutants were capable of forming covalent thymidylate synthase-5-fluorodUMP-methylenetetrahydrofolate complex; hence, the Asp side chain is not essential for steps leading to the covalent complex. We conclude that the hydrogen bond network between Asp 221 and the folate cofactor contributes to cofactor binding and a catalytic step after formation of the covalent ternary complex intermediate.

The separate effects of E60Q in Lactobacillus casei thymidylate synthase delineate between mechanisms for formation of intermediates in catalysis

X-Ray crystal structures of Lactobacillus casei thymidylate synthase (TS) mutant complexes of E60D with dUMP, and E60Q with dUMP or FdUMP, as well as ternary complexes with folate analog inhibitor CB3717, are described. The structures we report address the decrease in rate of formation of ternary complexes in the E60 mutants. Structures of ternary complexes of L.casei TS mimic ligand-bound TS just prior to covalent bond formation between ligands and protein. Ternary complex structures of L.casei TS E60Q show the ligands are not optimally aligned for making the necessary covalent bonds. Since CB3717 is an analog of the open, activated form of the cofactor, these structures suggest that the slow rate of ternary complex formation in E60 mutants is at least partly the result of impaired alignment of ligands in the active site after binding and activation of the cofactor. Binary complexes of TS E60Q and TS E60D with substrate (dUMP) show no change in dUMP position or occupancy. These results are consistent with the fact that Kd(dUMP) and Km(dUMP) are almost the same, and the rates of folate-independent debromination of 5-bromo-dUMP are even higher than for wild type TS.

Contributions of orientation and hydrogen bonding to catalysis in Asn229 mutants of thymidylate synthase

We have determined structures of binary and ternary complexes of five Asn229 variants of thymidylate synthase (TS) and related their structures to the kinetic constants measured previously. Asn229 forms two hydrogen bonds to the pyrimidine ring of the substrate 2'-deoxyuridine-5'-monophosphate (dUMP). These hydrogen bonds constrain the orientation of dUMP in binary complexes with dUMP, and in ternary complexes with dUMP and the TS cofactor, 5,10-methylene-5,6,7,8-tetrahydrofolate. In N229 mutants, where these hydrogen bonds cannot be made, dUMP binds in a misoriented or more disordered fashion. Most N229 mutants exhibit no activity for the dehalogenation of 5-bromo-dUMP, which requires correct orientation of dUMP against Cys198. Since bound dUMP forms the binding surface against which the pterin ring of cofactor binds, misorientation of dUMP results in higher Km values for cofactor. At the same time, binding of the cofactor aids in ordering and positioning dUMP for catalysis. Hydrophobic mutants, such as N229I, favor an arrangement of solvent molecules and side-chains around the ligands similar to that in a proposed transition state for ternary complex formation in wild-type TS, and kcat values are similar to the wild-type value. Smaller, more hydrophilic mutants favor arrangements of the solvent and side-chains surrounding the ligands that do not resemble the proposed transition state. These changes correspond to decreases in kcat of up to 2000-fold, with only modest increases in Km or Kd. These results are consistent with the proposal that the hydrogen-bonding network between water, dUMP and side-chains in the active-site cavity contributes to catalysis in TS. Asn229 has the unique ability to maintain this critical network, without sterically interfering with dUMP binding.

Production of a polyketide natural product in nonpolyketide-producing prokaryotic and eukaryotic hosts

The polyketides are a diverse group of natural products with great significance as human and veterinary pharmaceuticals. A significant barrier to the production of novel genetically engineered polyketides has been the lack of available heterologous expression systems for functional polyketide synthases (PKSs). Herein, we report the expression of an intact functional PKS in Escherichia coli and Saccharomyces cerevisiae. The fungal gene encoding 6-methylsalicylic acid synthase from Penicillium patulum was expressed in E. coli and S. cerevisiae and the polyketide 6-methylsalicylic acid (6-MSA) was produced. In both bacterial and yeast hosts, polyketide production required coexpression of 6-methylsalicylic acid synthase and a heterologous phosphopantetheinyl transferase that was required to convert the expressed apo-PKS to its holo form. Production of 6-MSA in E. coli was both temperature- and glycerol-dependent and levels of production were lower than those of P. patulum, the native host. In yeast, however, 6-MSA levels greater than 2-fold higher than the native host were observed. The heterologous expression systems described will facilitate the manipulation of PKS genes and consequent production of novel engineered polyketides and polyketide libraries.

Molecular recognition of tRNA by tRNA pseudouridine 55 synthase

Escherichia coli tRNA pseudouridine 55 synthase catalyzes pseudouridine formation at U55 in tRNA. A 17 base oligoribonucleotide analog of the T-arm was equivalent to intact native tRNA as a substrate for pseudouridine 55 synthase, viz., the features for substrate recognition by this enzyme are completely contained within the T-arm. The structures and activities of mutant tRNAs and T-arms were used to analyze substrate recognition by pseudouridine 55 synthase. The 17-mer T-arm was an excellent substrate for the synthase, while disruption of the stem structure of the 17-mer T-arm eliminated activity. Kinetic data on tRNA mutants lacking single T-stem base pairs indicated that only the 53:61 base pair, which maintains the 7 base loop size, was essential for activity. The identities of individual bases in the stem were unimportant provided base pairing was intact. A major function of the T-stem appears to be the maintainence of a stable stem-loop structure and proper presentation of the T-loop to pseudouridine 55 synthase. The 7 base T-loop could be expanded or contracted by 1 base and still retain activity, albeit with a 30-fold reduction in kcat. Kinetic analysis of T-loop mutants revealed the requirement for U54, U55, and A58, and a preference for C over U at position 56. Base substitutions at loop nonconserved position 59 or semiconserved positions 57 or 60 were well tolerated. Comparison of pseudouridine 55 synthase and tRNA (m5U54)-methyltransferase revealed that both enzymes required the stem-loop structure. However, pseudouridine 55 synthase was not stringent for a 7 base loop and recognized a consensus base sequence within the T-loop, while tRNA (m5U54)-methyltransferase recognized the secondary structure of the 7 member T-loop with only a specific requirement for U54, the T-loop substrate site. We conclude that recognition of tRNA by pseudouridine 55 synthase resides in the conformation of the T-arm plus four specific bases of the loop.

A conserved aspartate of tRNA pseudouridine synthase is essential for activity and a probable nucleophilic catalyst

tRNA pseudouridine synthase I catalyzes the conversion of uridine to pseudouridine at positions 38, 39, and/or 40 in the anticodon loop of many tRNAs. Pseudouridine synthase I was cloned behind a T7 promoter and expressed in Escherichia coli to about 20% of total soluble proteins. Fluorouracil-substituted tRNA caused a time-dependent inactivation of pseudouridine synthase I and formed a covalent complex with the enzyme that involved the FUMP at position 39. Asp60, conserved in all known and putative pseudouridine synthases, was mutated to amino acids with diverse side chains. All Asp60 mutants bound tRNA but were catalytically inactive and failed to form covalent complexes with fluorouracil-substituted tRNA. We conclude that the conserved Asp60 is essential for pseudouridine synthase activity and propose mechanisms which involve this residue in important catalytic roles.

A conserved aspartate of tRNA pseudouridine synthase is essential for activity and a probable nucleophilic catalyst

tRNA pseudouridine synthase I catalyzes the conversion of uridine to pseudouridine at positions 38, 39, and/or 40 in the anticodon loop of many tRNAs. Pseudouridine synthase I was cloned behind a T7 promoter and expressed in Escherichia coli to about 20% of total soluble proteins. Fluorouracil-substituted tRNA caused a time-dependent inactivation of pseudouridine synthase I and formed a covalent complex with the enzyme that involved the FUMP at position 39. Asp60, conserved in all known and putative pseudouridine synthases, was mutated to amino acids with diverse side chains. All Asp60 mutants bound tRNA but were catalytically inactive and failed to form covalent complexes with fluorouracil-substituted tRNA. We conclude that the conserved Asp60 is essential for pseudouridine synthase activity and propose mechanisms which involve this residue in important catalytic roles.

A novel dCMP methylase by engineering thymidylate synthase

X-ray crystal structures of binary complexes of dUMP or dCMP with the Lactobacillus caseiTS mutant N229D, a dCMP methylase, revealed that there is a steric clash between the 4-NH2 of dCMP and His 199, a residue which normally H-bonds to the 4-O of dUMP but is not essential for activity. As a result, the cytosine moiety of dCMP is displaced from the active site and the catalytic thiol is moved from the C6 of the substrate about 0.5 A further than in the wild-type TS-dUMP complex. We reasoned that combining the N229D mutation with mutations at residue 199 which did not impinge on the 4-NH2 of dCMP should correct the displacements and further favor methylation of dCMP. We therefore prepared several TS N229D mutants and characterized their steady state kinetic parameters. TS H199A/N229D showed a 10(11) change in specificity for methylation of dCMP versus dUMP. The structures of TS H199A/N229D in complex with dCMP and dUMP confirmed that the position and orientation of bound dCMP closely approaches that of dUMP in wild-type TS, whereas dUMP was displaced from the optimal catalytic binding site.

Plasmodium falciparum: asparagine mutant at residue 108 of dihydrofolate reductase is an optimal antifolate-resistant single mutant

The codon for serine residue 108 of the Plasmodium falciparum dihydrofolate reductase gene was replaced with those for the other 19 amino acids. Except for the Lys108 mutant, which was not expressed, all other substitutions yielded DHFR mutants which were expressed in Escherichia coli as inactive inclusion bodies. Nine of the mutants--Asn108, Thr108, Gly108, Ala108, Gln108, Cys108, Val108, Leu108, and Met108--yielded active DHFR upon refolding of the protein from the inclusion bodies. The remaining mutants--IIe108, Arg108, Pro108, Asp108, His108, Tyr108, Phe108, Trp108, and Glu108--did not exhibit detectable DHFR activity on refolding. The Asn108 mutant had almost unperturbed kinetic parameters but conferred resistance to pyrimethamine and cycloguanil; other active mutants showed poorer DHFR activity. We purified and characterized four mutants which produced highest DHFR activity, i.e., the Gln108, Gly108, Cys108, and Ala108 mutants. These mutant enzymes had kcat/K(m) values ranging from 7 to 22% of the wild-type enzyme. While DHFRs from Gly108, Cys108, and Ala108 mutants were as susceptible to pyrimethamine and cycloguanil as the wild type, the Gln108 mutation conferred high resistance to both inhibitors. Our data suggest that residue 108 is important for antifolate binding, and that the Ser108 to Asn108 mutation was selected in nature because of (i) the need for only a single base change, (ii) its good activity, and (iii) its resistance to antifolates.

Specificity in structure-based drug design: identification of a novel, selective inhibitor of Pneumocystis carinii dihydrofolate reductase

Specificity is an important aspect of structure-based drug design. Distinguishing between related targets in different organisms is often the key to therapeutic success. Pneumocystis carinii is a fungal opportunist which causes a crippling pneumonia in immunocompromised individuals. We report the identification of novel inhibitors of P. carinii dihydrofolate reductase (DHFR) that are selective versus inhibition of human DHFR using computational molecular docking techniques. The Fine Chemicals Directory, a database of commercially available compounds, was screened with the DOCK program suite to produce a list of potential P. carinii DHFR inhibitors. We then used a postdocking refinement directed at discerning subtle structural and chemical features that might reflect species specificity. Of 40 compounds predicted to exhibit anti-Pneumocystis DHFR activity, each of novel chemical framework, 13 (33%) show IC50 values better than 150 microM in an enzyme assay. These inhibitors were further assayed against human DHFR: 10 of the 13 (77%) bind preferentially to the fungal enzyme. The most potent compound identified is a 7 microM inhibitor of P. carinii DHFR with 25-fold selectivity. The ability of molecular docking methods to locate selective inhibitors reinforces our view of structure-based drug discovery as a valuable strategy, not only for identifying lead compounds, but also for addressing receptor specificity.

Construction of a homodimeric dihydrofolate reductase-thymidylate synthase bifunctional enzyme

A gene encoding a bifunctional homodimeric dihydrofolate reductase-thymidylate synthase (DHFR-TS) was constructed by destroying the stop codon of Escherichia coli dihydrofolate reductase (DHFR) and joining the coding sequences of the monofunctional enzymes by a five amino acid linker. The protein was designed to mimic features of active site proximity and electrostatics in the protozoan DHFR-TSs which are believed to be important in channeling of the DHFR substrate, H2folate, to TS. The genetically engineered catalytically active homodimeric bifunctional DHFR-TS was expressed, purified and characterized. The component activities of the purified bifunctional enzyme had kinetic properties similar to those of the monofunctional TS and DHFR, but unlike the authentic bifunctional enzymes from protozoa this enzyme did not kinetically channel dihydrofolate from DHFR to TS.

The dynamic NMR structure of the T psi C-loop: implications for the specificity of tRNA methylation

tRNA (m5U54)-methyltransferase (RUMT) catalyzes the S-adenosylmethionine-dependent methylation of uridine-54 in the T psi C-loop of all transfer RNAs in E. coli to form the 54-ribosylthymine residue. However, in all tRNA structures, residue 54 is completely buried and the question arises as to how RUMT gains access to the methylation site. A 17-mer RNA hairpin consisting of nucleotides 49-65 of the T psi-loop is a substrate for RUMT. Homonuclear NMR methods in conjunction with restrained molecular dynamics (MD) methods were used to determine the solution structure of the 17-mer T-arm fragment. The loop of the hairpin exhibits enhanced flexibility which renders the conventional NMR average structure less useful compared to the more commonly found situation where a molecule exists in predominantly one major conformation. However, when resorting to softer refinement methods such as MD with time-averaged restraints, the conflicting restraints in the loop can be satisfied much better. The dynamic structure of the T-arm is represented as an ensemble of 10 time-clusters. In all of these, U54 is completely exposed. The flexibility of the T psi-loop in solution in conjunction with extensive binding studies of RUMT with the T psi C-loop and tRNA suggest that the specificity of the RUMT/ tRNA recognition is associated with tRNA tertiary structure elements. For the methylation, RUMT would simply have to break the tertiary interactions between the D- and T-loops, leading to a melting of the T-arm structure and making U54 available for methylation.

Expression of a functional non-ribosomal peptide synthetase module in Escherichia coli by coexpression with a phosphopantetheinyl transferase

BACKGROUND

Non-ribosomal peptide synthetases (NRPSs) found in bacteria and fungi are multifunctional enzymes that catalyze the synthesis of a variety of biologically important peptides. These enzymes are composed of modular units, each responsible for the activation of an amino acid to an aminoacyl adenylate and for the subsequent formation of an aminoacyl thioester with the sulfhydryl group of a 4'-phosphopantetheine moiety. Attempts to express these modules in Escherichia coli have resulted in recombinant proteins deficient in 4'-phosphopantetheine. The recent identification of a family of phosphopantetheinyl transferases (P-pant transferases) associated with NRPS have led us to investigate whether coexpression of NRPS modules with P-pant transferases in E. coli would lead to the incorporation of 4'-phosphopantetheine.

RESULTS

A truncated module of gramicidin S synthetase, PheAT(His6), was expressed as a His6 fusion protein in E. coli with and without Gsp, the P-pant transferase associated with gramicidin S synthetase. Although PheAT(His6) expressed alone in E. coli catalyzed Phe-AMP formation from Phe and ATP, <1% was converted to the Phe thioester. In contrast, >80% of the PheAT(His6) that was coexpressed with Gsp could form the Phe thioester in the presence of Phe and ATP.

CONCLUSIONS

Our finding indicates the presence of an almost equimolar amount of 4'-phosphopantetheine covalently bound to the NRPS module PheAT(His6), and that the functional expression of NRPS modules in E. coli is possible, provided that they are coexpressed with an appropriate P-pant transferase.

Active site general catalysts are not necessary for some proton transfer reactions of thymidylate synthase

Several steps of the reaction catalyzed by thymidylate synthase (TS) require proton transfers to and from O-4 and C-5 of the pyrimidine moiety of substrate dUMP. It has been proposed that one or more of three active site residues-Glu60, His199, and Asn229-together with ordered water molecules serve as general catalysts in facilitating such proton transfers. These three residues, individually and together were mutated to residues incapable of proton transfer, and the mutant enzymes were purified and tested for activity in the formation of dTMP and the dehalogenation of 5-bromo- and 5-iodo-dUMP. The dehalogenation reaction pathway shares at least two direct chemical counterparts with the TS reaction pathway which are believed to involve general acid/base catalysis-namely, the addition and elimination of the catalytic Cys of TS at C-6 of the pyrimidine substrate. Generally, the mutations had detrimental effects on dTMP synthesis with the triple mutant being completely inactive. In contrast, single mutants TS E601, and H199A and, interestingly, the triple mutant stripped of all three active site catalysts catalyzed the dehalogenation reaction as well as or better than the wild-type enzyme. It was concluded that addition and elimination reactions involving the 5.6-bond of pyrimidine substrates do not require general acid/base catalysis or, alternatively, the water molecules in the TS active site serve this role. The function(s) of the triad of general catalysts resides elsewhere in the reaction pathway leading to dTMP synthesis.

Antifolate-resistant mutants of Plasmodium falciparum dihydrofolate reductase

Single and multiple mutations at residues 16, 51, 59, 108, and 164 of Plasmodium falciparum dihydrofolate reductase (pfDHFR) have been linked to antifolate resistance in malaria. We prepared and characterized all seven of the pfDHFR mutants found in nature, as well as six mutants not observed in nature. Mutations involving residues 51, 59, 108, or 164 conferred cross resistance to both the antifolates pyrimethamine and cycloguanil, whereas mutation of residue 16 specifically conferred resistance to cycloguanil. The antifolate resistance of enzyme mutants found in nature correlated with in vivo antifolate resistance; however, mutants not found in nature were either poorly resistant or had insufficient catalytic activity to support DNA synthesis. Thus, specific combinations of multiple mutations at target residues were selected in nature to optimize resistance. Further, the resistance of multiple mutants was more than the sum of the component single mutations, indicating that residues were selected for their synergistic as well as intrinsic effects on resistance. Pathways inferred for the evolution of pyrimethamine-resistant mutants suggested that all multiple mutants emerged from stepwise selection of the single mutant, S108N. Thus, we propose that drugs targeted to both the wild-type pfDHFR and S108N mutant would have a low propensity for developing resistance, and hence could provide effective antimalarial agents.

Chemical synthesis of the Plasmodium falciparum dihydrofolate reductase-thymidylate synthase gene

Plasmodium falciparum dihydrofolate reductase-thymidylate synthase (DHFR-TS) is a well-known target for pyrimethamine and cycloguanil. The low amounts of enzyme obtainable from parasites or the currently available heterologous expression systems have thus far hindered studies of this enzyme. The 1912-base pair P. falciparum DHFR-TS gene was designed based on E. coli codon preference with unique restriction sites evenly placed throughout the coding sequence. The gene was designed and synthesized as three separated domains: the DHFR domain, the junctional sequence, and the TS domain. Each of these domains contained numerous unique restriction sites to facilitate mutagenesis. The three domains were assembled into a complete DHFR-TS gene which contained 30 unique restriction sites in the coding sequence. The bifunctional DHFR-TS was expressed from the synthetic gene as soluble enzyme in E. coli about 10-fold more efficiently than from the wild-type sequence. The DHFR-TS from the synthetic gene had kinetic properties similar to those of the wild-type enzyme and represents a convenient source of protein for further study. The unique restriction sites in the coding sequence permits easy mutagenesis of the gene which should facilitate further understanding of the molecular basis of antifolate resistance in malaria.

Identification of new RNA modifying enzymes by iterative genome search using known modifying enzymes as probes

The complete nucleotide sequences of the Haemophilus influenzae and Mycoplasma genitalium genomes and the partially sequenced Escherichia coli chromosome were analyzed to identify open reading frames (ORFs) likely to encode RNA modifying enzymes. The protein sequences of known RNA modifying enzymes from three families--m5U methyltransferases, psi synthases and 2'-O methyltransferases--were used as probes to search sequence databases for homologs. ORFs identified as homologous to the initial probes were retrieved and used as new probes against the databases in an iterative manner until no more homologous ORFs could be identified. Using this approach, we have identified two new m5U methyltransferases, seven new psi synthases and four new 2'-O methyltransferases in E. coli. Many of the ORFs found in E.coli have direct genetic counterparts (orthologs) in one or both of H.influenzae and M.genitalium. Since there is a near-complete knowledge of RNA modifications in E.coli, functional activities of the proteins encoded by the identified ORFs were proposed based on the level of conservation of the ORFs and the modified nucleotides.

Recognition of the T-arm of tRNA by tRNA (m5U54)-methyltransferase is not sequence specific

tRNA (m5U54)-methyltransferase (RUMT) catalyzes the methylation of U54 of tRNAs. In contrast to enzymes which recognize a particular tRNA, RUMT recognizes features common to all tRNAs. We have shown that these features reside in the T-arm of tRNA and constructed a minimal consensus sequence for RUMT recognition and catalysis (Gu et al., 1991b). Here, we have mutated each conserved T-loop residue and conserved T-stem base pair to bases or base pairs which are not observed in Escherichia coli tRNA. The substrate specificity of RUMT for 30 in vitro synthesized T-arm mutants of tRNAPhe and 37 mutants of the 17-mer analog of the T-arm derived from tRNA1Val was investigated. A 2-5 base pair stem was essential for recognition of the T-arm by RUMT, but the base composition of the stem was unimportant. The 7-base size of the T-loop maintained by the stem was essential for RUMT recognition. For tRNA, most base substitutions in the 7-base loop did not eliminate RUMT activity, except for any mutation of the methyl acceptor U54 and the C56G mutation. The effect of base and base pair mutations on Kcat or the rate of methylation by RUMT was more striking than the effect on the Kd for binding to RUMT. In comparison with mutations in the T-loop of intact tRNA, base mutation in the T-loop of the 17-mer T-arm had a more deleterious effect on binding and methylation. Surprisingly, recognition of tRNA by RUMT appears to reside in the three-dimensional structure of the seven-member T-loop rather than in its primary structure.

Functional expression of the dihydrofolate reductase domain of Leishmania major dihydrofolate reductase-thymidylate synthase bifunctional protein

The dihydrofolate reductase (DHFR) domain of the bifunctional dihydrofolate reductase-thymidylate synthase from Leishmania major has been subcloned and expressed as a soluble protein in Escherichia coli strain PA414 harboring plasmid pLMDHFR. Homogeneous L. major DHFR was obtained by chromatography on methotrexate-Sepharose followed by DE52. The purified enzyme migrated as a single 25-kDa protein on SDS-PAGE. The native molecular weight was determined to be 26 kDa, indicating that the isolated domain is a monomer. N-terminal sequence analysis revealed that serine, the second amino acid in the coding sequence, was the N-terminal amino acid of the protein. The enzyme showed a pH optimum similar to that of the bifunctional protein. For purified DHFR, the Km values were <1.0 microM for H2folate and <1.0 microM for NADPH. The kcat of the most active DHFR preparation was 5 s-1. The Km and kcat values were similar to those of the bifunctional enzyme.

Covalent reinforcement of a fragile region in the dimeric enzyme thymidylate synthase stabilizes the protein against chaotrope-induced unfolding

Urea and guanidinium chloride induced unfolding of thymidylate synthase, a dimeric enzyme, and engineered interface mutants have been monitored by circular dichroism, fluorescence, and size-exclusion chromatography. Equilibrium unfolding studies show biphasic transitions, with a plateau between 3.5 and 5 M urea, when monitored by far-UV CD and fluorescence energy transfer employing an (aminoethylamino) naphthalenesulfonyl (AEDANS) label at the active site residue, Cys198. AEDANS was also specifically incorporated at position Cys155 in the mutant protein T155C. Direct excitation of this extrinsic fluorophore in the wild type protein (labeled at Cys198) and mutant T155C (labeled at Cys155) showed remarkable differences in the unfolding profiles. C155 AEDANS has a transition centered at 3.5 M urea, which is in contrast to Cys 198 AEDANS (5.5 M urea). Unfolding studies monitored by following intrinsic fluorescence of Trp residues which are located in a small structural domain suggest that this region of the protein is intrinsically fragile. The stable equilibrium intermediate is identified to be an ensemble of partially unfolded aggregated species by gel filtration studies. The chaotrope-induced denaturation of TS appears to proceed through a partially unfolded intermediate that is stabilized by aggregation. Dissociation and loss of structure occur concomitantly at high denaturant concentrations. Introduction of two symmetrically positioned disulfide bridges across the dimer interface in the triple mutant T155C/E188C/C244T (TSMox) stabilized the protein against denaturant-induced unfolding. Aggregate formation was completely abolished in the mutant TSMox, which also enhanced the overall structural stability of the protein. Structural reinforcement of the fragile interface in thymidylate synthase results in dramatic stabilization toward chaotrope-induced unfolding.

Heterologous expression and characterization of the bifunctional dihydrofolate reductase-thymidylate synthase enzyme of Toxoplasma gondii

We have expressed catalytically active Toxoplasma gondii dihydrofolate-thymidylate synthase (DHFR-TS) and the individual TS and DHFR domains in Escherichia coli using the T7 promoter of pET-15b. DHFR-TS constituted approximately 10% of the total soluble cell protein and was purified using methotrexate-Sepharose chromatography to yield 10 mg of homogeneous DHFR-TS per liter of culture. The DHFR domain was recovered as insoluble inclusion bodies which could be unfolded and refolded to recover soluble, active enzyme. The TS domain was overexpressed as a soluble protein by growing the cells at 24 degrees C; this is the first report of the expression of an active TS domain from a bifunctional enzyme. The kcat and K(m) values for DHFR-TS are similar to those of other previously characterized protozoan DHFRs and TSs. The antimicrobial antifolates, TMP and Pyr, inhibit DHFR activity of the bifunctional protein in accord with their effects in crude enzyme preparations and in vivo systems. Kinetic parameters and Ki values for TMP and Pyr with the isolated DHFR domain were identical to the values for DHFR in the bifunctional enzyme. Evidence of kinetic channeling of the dihydrofolate product of TS to the DHFR domain in the bifunctional enzyme was obtained by kinetic and inhibition studies. Properties such as yield, stability, and activities of the recombinant T. gondii DHFR-TS provide clear advantages over other bifunctional DHFR-TSs as a model for future studies.

Partitioning roles of side chains in affinity, orientation, and catalysis with structures for mutant complexes: asparagine-229 in thymidylate synthase

Thymidylate synthase (TS) methylates only dUMP, not dCMP. The crystal structure of TS.dCMP shows sCMP 4-NH2 excluded from the space between Asn-229 and His-199 by the hydrogen bonding and steric properties and Asn-229. Consequently, 6-C of dCMP is over 4 A from the active site sulfhydryl. The Asn-229 side chain is prevented from flipping 180 degrees to and orientation the could hydrogen bond to dCMP by a hydrogen bond network between conserved residues. Thus, the specific binding of dUMP by TS results from occlusion of competing substrates by steric and electronic effects of residues in the active site cavity. When Asn-229 is replaced by a cysteine, the Cys-229 S gamma rotates out of the active site, and the mutant enzyme binds both dCMP and dUMP tightly but does not methylate dCMP. Thus simply admitting dCMP into the dUMP binding site of TS is not sufficient for methylation of dCMP. Structures of nucleotide complexes of TS N229D provide a reasonable explanation for the preferential methylation of dCMP instead of dUMP by this mutant. In TS N229D.dCMP, Asp-229 forms hydrogen bonds to 3-N and 40NH2 of dCMP. Neither the Asp-229 carboxyl moiety nor ordered water appears to hydrogen bond to 4-O of dUMP. Hydrogen bonds to 4-O (or 4-NH2) have been proposed to stabilize reaction intermediates. If their absence in TS N229D.dUMP persists in the ternary complex, it could explain the 10(4)-fold decrease in kcat/Km for dUMP.

Asparagine 229 mutants of thymidylate synthase catalyze the methylation of 3-methyl-2'-deoxyuridine 5'-monophosphate

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 2'-deoxyuridine 5'-monophosphate (dUMP). Asn 229 is not essential for substrate binding or catalysis [Liu, l., & Santi, D. B. (1993) Proc. Natl. Acad. Sci. U.S.A. 90, 8604-8608] but is a major determinant in substrate specificity [Liu, l., & Santi, D. V. (1993) Biochemistry 32, 9263-9267]. 3-Methyl-dUMP (3-MedUMP) is neither a substrate nor an inhibitor of wild type TS but is converted to 3-methyl 2'-deoxythymidine 5'-monophosphate by many TS Asn 229 mutants. Some of the Asn 229 mutants (N229C, -I, -M, -A, and -V) have kcat values for 3-MedUMP methylation which are up to about 20% of that for wild type TS-catalyzed methylation of dUMP, and some mutants (N229C and -A) catalyze methylation of 3-MedUMP more efficiently than that of dUMP. Mutants with hydrophobic side chains tended to be more active in catalysis of methylation of 3-MedUMP than those with hydrophilic side chains. The ability of 3-MedUMP to serve as a substrate for Asn 229 mutants shows that the active form of dUMP involves the neutral pyrimidine base and that ionization of the 3-NH group does not occur in the course of catalysis. In contrast to the negligible binding of 3-MedUMP to wild type TS, both 3-MedUMP and dUMP showed similar Km values with the Asn 229 mutants, suggesting similar binding affinities to the mutants. The X-ray crystal structure of the TS N229C--3-MedUMP complex showed that the side chain of Cys 229 was rotated away from the pyrimidine ring to allow placement of a water molecule and the 3-methyl group of 3-MedUMP in the active site. Our results suggest that the inability of 3-MedUMP to undergo methylation by wild type TS is due to its inability to bind to the enzyme, which in turn is simply a result of steric interference of the 3-methyl group with the side chain of Asn 229.

Interaction of tRNA (uracil-5-)-methyltransferase with NO2Ura-tRNA

tRNA in which uracil is completely replaced by 5-nitro-uracil was prepared by substituting 5-nitro-UTP for UTP in an in vitro transcription reaction. The rationale was that the 5-nitro substituent activates the 6-carbon of the Ura heterocycle towards nucleophiles, and hence could provide mechanism-based inhibitors of enzymes which utilize this feature in their catalytic mechanism. When assayed shortly after mixing, the tRNA analog, NO2Ura-tRNA, is a potent competitive inhibitor of tRNA-Ura methyl transferase (RUMT). Upon incubation, the analog causes a time-dependent inactivation of RUMT which could be reversed by dilution into a large excess of tRNA substrate. Covalent RUMT-NO2Ura-tRNA complexes could be isolated on nitrocellulose filters or by SDS-PAGE. The interaction of RUMT and NO2Ura-tRNA was deduced to involve formation of a reversible complex, followed by formation of a reversible covalent complex in which Cys 324 of RUMT is linked to the 6-position of NO2Ura 54 in NO2Ura-tRNA.