Variants of human thymidylate synthase with loop 181–197 stabilized in the inactive conformation

Loop 181–197 of human thymidylate synthase (hTS) populates two major conformations, essentially corresponding to the loop flipped by 180°. In one of the conformations, the catalytic Cys195 residue lies distant from the active site making the enzyme inactive. Ligands stabilizing this inactive conformation may function as allosteric inhibitors. To facilitate the search for such inhibitors, we have expressed and characterized several mutants designed to shift the equilibrium toward the inactive conformer. In most cases, the catalytic efficiency of the mutants was only somewhat impaired with values of k_cat/K_m reduced by factors in a 2–12 range. One of the mutants, M190K, is however unique in having the value of k_cat/K_m smaller by a factor of ～7500 than the wild type. The crystal structure of this mutant is similar to that of the wt hTS with loop 181–197 in the inactive conformation. However, the direct vicinity of the mutation, residues 188–194 of this loop, assumes a different conformation with the positions of C_α shifted up to 7.2 Å. This affects region 116–128, which became ordered in M190K while it is disordered in wt. The conformation of 116–128 is however different than that observed in hTS in the active conformation. The side chain of Lys190 does not form contacts and is in solvent region. The very low activity of M190K as compared to another mutant with a charged residue in this position, M190E, suggests that the protein is trapped in an inactive state that does not equilibrate easily with the active conformer.     

Human thymidylate synthase with loop 181-197 stabilized in an inactive conformation: ligand interactions, phosphorylation, and inhibition profiles

Thymidylate synthase (TS) is a well-validated cancer target that undergoes conformational switching between active and inactive states. Two mutant human TS (hTS) proteins are predicted from crystal structures to be stabilized in an inactive conformation to differing extents, with M190K populating the inactive conformation to a greater extent than A191K. Studies of intrinsic fluorescence and circular dichroism revealed that the structures of the mutants differ from those of hTS. Inclusion of the substrate dUMP was without effect on M190K but induced structural changes in A191K that are unique, relative to hTS. The effect of strong stabilization in an inactive conformation on protein phosphorylation by casein kinase 2 (CK2) was investigated. M190K was highly phosphorylated by CK2 relative to an active-stabilized mutant, R163K hTS. dUMP had no detectable effect on phosphorylation of M190K; however, dUMP inhibited phosphorylation of hTS and R163K. Studies of temperature dependence of catalysis revealed that the E(act) and temperature optimum are higher for A191K than hTS. The potency of the active-site inhibitor, raltitrexed, was lower for A191K than hTS. The response of A191K to the allosteric inhibitor, propylene diphosphonate (PDPA) was concentration dependent. Mixed inhibition was observed at low concentrations; at higher concentrations, A191K exhibited nonhyperbolic behavior with respect to dUMP and inhibition of catalysis was reversed by substrate saturation. In summary, inactive-stabilized mutants differ from hTS in thermal stability and response to substrates and PDPA. Importantly, phosphorylation of hTS by CK2 is selective for the inactive conformation, providing the first indication of physiological relevance for conformational switching.     

Crystal structures of thymidylate synthase mutant R166Q: structural basis for the nearly complete loss of catalytic activity

Thymidylate synthase (TS) catalyzes the folate-dependent methylation of deoxyuridine monophosphate (dUMP) to form thymidine monophosphate (dTMP). We have investigated the role of invariant arginine 166, one of four arginines that contact the dUMP phosphate, using site-directed mutagenesis, X-ray crystallography, and TS from Escherichia coli. The R166Q mutant was crystallized in the presence of dUMP and a structure determined to 2.9 A resolution, but neither the ligand nor the sulfate from the crystallization buffer was found in the active site. A second structure determined with crystals prepared in the presence of dUMP and the antifolate 10-propargyl-5,8-dideazafolate revealed that the inhibitor was bound in an extended, nonproductive conformation, partially occupying the nucleotide-binding site. A sulfate ion, rather than dUMP, was found in the nucleotide phosphate-binding site. Previous studies have shown that the substitution at three of the four arginines of the dUMP phosphate-binding site is permissive; however; for Arg166, all the mutations lead to a near-inactive mutant. The present structures of TS R166Q reveal that the phosphate-binding site is largely intact, but with a substantially reduced affinity for phosphate, despite the presence of the three remaining arginines. The position of Cys146, which initiates catalysis, is shifted in the mutant and resides in a position that interferes with the binding of the dUMP pyrimidine moiety.     

Human thymidylate synthase is in the closed conformation when complexed with dUMP and raltitrexed, an antifolate drug

Thymidylate synthase (TS) is a major target in the chemotherapy of colorectal cancer and some other neoplasms while raltitrexed (Tomudex, ZD1694) is an antifolate inhibitor of TS approved for clinical use in several European countries. The crystal structure of the complex between recombinant human TS, dUMP, and raltitrexed has been determined at 1.9 A resolution. In contrast to the situation observed in the analogous complex of the rat TS, the enzyme is in the closed conformation and a covalent bond between the catalytic Cys 195 and dUMP is present in both subunits. This mode of ligand binding is similar to that of the analogous complex of the Escherichia coli enzyme. The only major differences observed are a direct hydrogen bond between His 196 and the O4 atom of dUMP and repositioning of the side chain of Tyr 94 by about 2 A. The thiophene ring of the drug is disordered between two parallel positions.     

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

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

Role of an invariant lysine residue in folate binding on Escherichia coli thymidylate synthase: calorimetric and crystallographic analysis of the K48Q mutant

Thymidylate synthase (TS) catalyzes the reductive methylation of deoxyuridine monophosphate (dUMP) using methylene tetrahydrofolate (CH(2)THF) as cofactor, the glutamate tail of which forms a water-mediated hydrogen bond with an invariant lysine residue of this enzyme. To understand the role of this interaction, we studied the K48Q mutant of Escherichia coli TS using structural and biophysical methods. The k(cat) of the K48Q mutant was 430-fold lower than wild-type TS in activity, while the K(m) for the (R)-stereoisomer of CH(2)THF was 300 microM, about 30-fold larger than K(m) from the wild-type TS. Affinity constants were determined using isothermal titration calorimetry, which showed that binding was reduced by one order of magnitude for folate-like TS inhibitors, such as propargyl-dideazafolate (PDDF) or compounds that distort the TS active site like BW1843U89 (U89). The crystal structure of the K48Q-dUMP complex revealed that dUMP binding is not impaired in the mutant, and that U89 in a ternary complex of K48Q-nucleotide-U89 was bound in the active site with subtle differences relative to comparable wild-type complexes. PDDF failed to form ternary complexes with K48Q and dUMP. Thermodynamic data correlated with the structural determinations, since PDDF binding was dominated by enthalpic effects while U89 had an important entropic component. In conclusion, K48 is critical for catalysis since it leads to a productive CH(2)THF binding, while mutation at this residue does not affect much the binding of inhibitors that do not make contact with this group.     

Cooperative inhibition of human thymidylate synthase by mixtures of active site binding and allosteric inhibitors

Thymidylate synthase (TS) is a target in the chemotherapy of colorectal cancer and some other neoplasms. It catalyzes the transfer of a methyl group from methylenetetrahydrofolate to dUMP to form dTMP. On the basis of structural considerations, we have introduced 1,3-propanediphosphonic acid (PDPA) as an allosteric inhibitor of human TS (hTS); it is proposed that PDPA acts by stabilizing an inactive conformer of loop 181-197. Kinetic studies showed that PDPA is a mixed (noncompetitive) inhibitor versus dUMP. In contrast, versus methylenetrahydrofolate at concentrations lower than 0.25 microM, PDPA is an uncompetitive inhibitor, while at PDPA concentrations higher than 1 microM the inhibiton is noncompetive, as expected. At the concentrations corresponding to uncompetitive inhibition, PDPA shows positive cooperativity with an antifolate inhibitor, ZD9331, which binds to the active conformer. PDPA binding leads to the formation of hTS tetramers, but not higher oligomers. These data are consistent with a model in which hTS exists preferably as an asymmetric dimer with one subunit in the active conformation of loop 181-197 and the other in the inactive conformation.     

The active conformation of glutamate synthase and its binding to ferredoxin

Glutamate synthases (GltS) are crucial enzymes in ammonia assimilation in plants and bacteria, where they catalyze the formation of two molecules of L-glutamate from L-glutamine and 2-oxoglutarate. The plant-type ferredoxin-dependent GltS and the functionally homologous alpha subunit of the bacterial NADPH-dependent GltS are complex four-domain monomeric enzymes of 140-165 kDa belonging to the NH(2)-terminal nucleophile family of amidotransferases. The enzymes function through the channeling of ammonia from the N-terminal amidotransferase domain to the FMN-binding domain. Here, we report the X-ray structure of the Synechocystis ferredoxin-dependent GltS with the substrate 2-oxoglutarate and the covalent inhibitor 5-oxo-L-norleucine bound in their physically distinct active sites solved using a new crystal form. The covalent Cys1-5-oxo-L-norleucine adduct mimics the glutamyl-thioester intermediate formed during L-glutamine hydrolysis. Moreover, we determined a high resolution structure of the GltS:2-oxoglutarate complex. These structures represent the enzyme in the active conformation. By comparing these structures with that of GltS alpha subunit and of related enzymes we propose a mechanism for enzyme self-regulation and ammonia channeling between the active sites. X-ray small-angle scattering experiments were performed on solutions containing GltS and its physiological electron donor ferredoxin (Fd). Using the structure of GltS and the newly determined crystal structure of Synechocystis Fd, the scattering experiments clearly showed that GltS forms an equimolar (1:1) complex with Fd. A fundamental consequence of this result is that two Fd molecules bind consecutively to Fd-GltS to yield the reduced FMN cofactor during catalysis.     

The active-inactive transition of human thymidylate synthase: targeted molecular dynamics simulations

Human thymidylate synthase (hTS) is an established anticancer target. It catalyses the production of 2'-deoxythymidine-5'-monophosphate, an essential building block for DNA synthesis. Because of the development of cellular drug resistance against current hTS inhibitors, alternative inhibition strategies are needed. hTS exists in two forms, active and inactive, defined by the conformation of the active-site (AS) loop, which carries the catalytic cysteine, C195. To investigate the mechanism of activation and inactivation, targeted molecular dynamics (TMD) simulations of the transitions between active and inactive states of hTS were performed. Analysis of changes in the dihedral angles in the AS loop during different TMD simulations revealed complex conformational transitions. Despite hTS being a homodimeric enzyme and the conformational transition significantly involving the dimer interface, the transition occurs in an asymmetric, sequential manner via an ensemble of pathways. In addition to C195, which reoriented during the simulations, other key residues in the rotation of the AS loop included W182 and R185. The interactions of the cognate bulky W182 residues at the dimer interface hindered the simultaneous twist of the AS loops in the hTS dimer. Interactions of R185, which is unique for hTS, with ligands at different allosteric sites affected the activation transition. In addition to providing insights into the activation/inactivation mechanism of hTS and how conformational transitions can occur in homodimeric proteins, our observations suggest that blocking of AS loop rotation by ligands binding in the large cavity between the loops could be one way to stabilize inactive hTS and inhibit the enzyme.     

The active site cysteine of arginine kinase: structural and functional analysis of partially active mutants

Arginine kinase buffers cellular ATP levels by catalyzing reversible phosphoryl transfer between ATP and arginine. A conserved cysteine has long been thought important in catalysis. Here, cysteine 271 of horseshoe crab arginine kinase has been mutated to serine, alanine, asparagine, or aspartate. Catalytic turnover rates were 0.02-1.0% of wild type, but the activity of uncharged mutations could be partially rescued with chloride. Steady-state binding constants were slightly increased, more so for phospho-L-arginine than ADP. Substrate binding synergy observed in many phosphagen kinases was reduced or eliminated in mutant enzymes. The crystallographic structure of the alanine mutant at 2.3 A resolution, determined as a transition state analogue complex with arginine, nitrate, and MgADP, was nearly identical to wild type. Enzyme-substrate interactions are maintained as in wild type, and substrates remain at least roughly aligned for in-line phosphoryl transfer. Homology models with serine, asparagine, or aspartate replacing the active site cysteine similarly show only minor structural changes. Most striking, however, is the presence in the C271A mutant crystallographic structure of a chloride ion within 3.5 A of the nonreactive N(eta) substrate nitrogen, approximating the position of the sulfur in the wild-type's cysteine. Together, the results contradict prevailing speculation that the cysteine mediates a substrate-induced conformational change, confirm that it is the thiolate form that is relevant to catalysis, and suggest that one of its roles is to help to enhance the catalytic rate through electrostatic stabilization of the transition state.     

Dihydrofolate reductase and thymidylate synthase in plants: an open problem

This review deals with recent findings in the purification and characterization of dihydrofolate reductase (DHFR) and thymidylate synthase (TS) in plants. The few enzymes purified, which differ remarkably in regard to their structure. kinetic and molecular properties and subcellular location are described. The response of DHFRs to antifolic agents and the analysis of resistance mechanisms in isolated cell lines is also reported. Problems opened by recent studies of the enzymes isolated from plants are outlined.     

Polymorphisms of folate pathway enzymes (methylenetetrahydrofolate reductase and thymidylate synthase) and their relationship with thymidylate synthase expression in human astrocytic tumors

Two important polymorphisms of folate cycle enzymes, methylenetetrahydrofolate reductase (MTHFR) C677T and thymidylate synthase (TS) enhancer region (TSER) 28-bp tandem repeat, are related to risk of various types of cancer, including brain tumors, although there are few studies on this subject. A case-control study of these two polymorphisms in astrocytomas of different grades was carried out using polymerase chain reaction-restriction fragment length polymorphism, also determining the immunohistochemical expression of TS. The MTHFR 677 TT genotype was less associated with astrocytic tumors (odds ratio [OR]=0.00; p=0.0238), but the TSER polymorphism did not show any significant association. Combined genotype TT-double repeats/triple repeats (2R/3R) had a protective effect against astrocytomas (OR=0.00; p=0.0388). Expression of TS protein was observed in the majority of cases, with grade IV tumors being the exception. Moreover, the median H-score for the pilocytic astrocytomas was significantly higher when compared with that for diffuse tumors. There was an inverse correlation between the 2R/2R genotype and the highest TS-expressing tumors, and 3R/3R was relatively more frequent among the tumors grouped in the third and fourth quartiles. Our results provide support for the role of MTHFR and TS polymorphism in gliomagenesis, possibly because of the alteration of DNA methylation and repair status. Moreover, high levels of TS expression were detected in these tumors.     

A theoretical study of the active sites of papain and S195C rat trypsin: implications for the low reactivity of mutant serine proteinases.

The serine and cysteine proteinases represent two important classes of enzymes that use a catalytic triad to hydrolyze peptides and esters. The active site of the serine proteinases consists of three key residues, Asp...His...Ser. The hydroxyl group of serine functions as a nucleophile and the imidazole ring of histidine functions as a general acid/general base during catalysis. Similarly, the active site of the cysteine proteinases also involves three key residues: Asn, His, and Cys. The active site of the cysteine proteinases is generally believed to exist as a zwitterion (Asn...His+...Cys-) with the thiolate anion of the cysteine functioning as a nucleophile during the initial stages of catalysis. Curiously, the mutant serine proteinases, thiol subtilisin and thiol trypsin, which have the hybrid Asp...His...Cys triad, are almost catalytically inert. In this study, ab initio Hartree-Fock calculations have been performed on the active sites of papain and the mutant serine proteinase S195C rat trypsin. These calculations predict that the active site of papain exists predominately as a zwitterion (Cys-...His+...Asn). However, similar calculations on S195C rat trypsin demonstrate that the thiol mutant is unable to form a reactive thiolate anion prior to catalysis. Furthermore, structural comparisons between native papain and S195C rat trypsin have demonstrated that the spatial juxtapositions of the triad residues have been inverted in the serine and cysteine proteinases and, on this basis, I argue that it is impossible to convert a serine proteinase to a cysteine proteinase by site-directed mutagenesis.     

Induction of intrachromosomal homologous recombination in human cells by raltitrexed, an inhibitor of thymidylate synthase

Thymidylate deprivation brings about "thymineless death" in prokaryotes and eukaryotes. Although the precise mechanism for thymineless death has remained elusive, inhibition of the enzyme thymidylate synthase (TS), which catalyzes the de novo synthesis of TMP, has served for many years as a basis for chemotherapeutic strategies. Numerous studies have identified a variety of cellular responses to thymidylate deprivation, including disruption of DNA replication and induction of DNA breaks. Since stalled or collapsed replication forks and strand breaks are generally viewed as being recombinogenic, it is not surprising that a link has been demonstrated between recombination induction and thymidylate deprivation in bacteria and lower eukaryotes. A similar connection between recombination and TS inhibition has been suggested by studies done in mammalian cells, but the relationship between recombination and TS inhibition in mammalian cells had not been demonstrated rigorously. To gain insight into the mechanism of thymineless death in mammalian cells, in this work we undertook a direct investigation of recombination in human cells treated with raltitrexed (RTX), a folate analog that is a specific inhibitor of TS. Using a model system to study intrachromosomal homologous recombination in cultured fibroblasts, we provide definitive evidence that treatment with RTX can stimulate accurate recombination events in human cells. Gene conversions not associated with crossovers were specifically enhanced several-fold by RTX. Additional experiments demonstrated that recombination events provoked by a double-strand break (DSB) were not impacted by treatment with RTX, nor was error-prone DSB repair via nonhomologous end-joining. Our work provides evidence that thymineless death in human cells is not mediated by corruption of DSB repair processes and suggests that an increase in chromosomal recombination may be an important element of cellular responses leading to thymineless death.     

The reactivity and oxidation pathway of cysteine 232 in recombinant human alpha 1-antitrypsin

Oxidative damage to the sulfur-containing amino acids, methionine and cysteine, is a major concern in biotechnology and medicine. alpha1-Antitrypsin, which is a metastable and conformationally flexible protein that belongs to the serpin family of protease inhibitors, contains nine methionines and a single cysteine in its primary sequence. Although it is known that methionine oxidation in the protein active site results in a loss of biological activity, there is little specific knowledge regarding the reactivity of its unpaired thiol, Cys-232. In this study, the thiol-modifying reagent NBD-Cl (7-chloro-4-nitrobenz-2-oxa-1,3-diazole) was used to label peroxide-modified alpha1-antitrypsin and demonstrate that the Cys-232 in vitro oxidation pathway begins with a stable sulfenic acid intermediate and is followed by the formation of sulfinic and cysteic acid in successive steps. pH-dependent reactivity with hydrogen peroxide showed that Cys-232 has a pK(a) of 6.86 +/- 0.05, a value that is more than 1.5 pH units lower than that of a typical protein thiol. pH-induced conformational changes in the region surrounding Cys-232 were also examined and indicate that mildly acidic conditions induce a conformation that enhances Cys-232 reactivity. In summary, this work provides new insights into alpha1-antitrypsin reactivity in oxidizing environments and shows that a unique structural environment renders its unpaired thiol, Cys-232, its most reactive amino acid.     

The structural roles of conserved Pro196, Pro197 and His199 in the mechanism of thymidylate synthase

We generated replacement sets for three highly conserved residues, Pro196, Pro197 and His199, that flank the catalytic nucleophile, Cys198. Pro196 and Pro197 have restricted mobility that could be important for the structural transitions known to be essential for activity. To test this hypothesis we obtained and characterized 13 amino acid substitutions for Pro196, 14 for Pro197 and 14 for His199. All of the Pro196 and Pro197 variants, except P197R, and four of the His199 variants complemented TS-deficient Escherichia coli cells, indicating they had at least 1% of wild-type activity. For all His199 mutations, k(cat)/K(m) for substrate and cofactor decreased more than 40-fold, suggesting that the conserved hydrogen bond network co-ordinated by His199 is important for catalysis. Pro196 can be substituted with small hydrophilic residues with little loss in k(cat), but 15- to 23-fold increases in K(m)(dUMP). Small hydrophobic substitutions for Pro197 were most active, and the most conservative mutant, P197A, had only a 5-fold lower k(cat)/K(m)(dUMP) than wild-type TS. Several Pro196 and Pro197 variants were temperature sensitive. The small effects of Pro196 or Pro197 mutations on enzyme kinetics suggest that the conformational restrictions encoded by the Pro-Pro sequence are largely maintained when either member of the pair is mutated.     

The human Rad51 K133A mutant is functional for DNA double-strand break repair in human cells

The human Rad51 protein requires ATP for the catalysis of DNA strand exchange, as do all Rad51 and RecA-like recombinases. However, understanding the specific mechanistic requirements for ATP binding and hydrolysis has been complicated by the fact that ATP appears to have distinctly different effects on the functional properties of human Rad51 versus yeast Rad51 and bacterial RecA. Here we use RNAi methods to test the function of two ATP binding site mutants, K133R and K133A, in human cells. Unexpectedly, we find that the K133A mutant is functional for repair of DNA double-strand breaks when endogenous Rad51 is depleted. We also find that the K133A protein maintains wild-type-like DNA binding activity and interactions with Brca2 and Xrcc3, properties that undoubtedly promote its DNA repair capability in the cell-based assay used here. Although a Lys to Ala substitution in the Walker A motif is commonly assumed to prevent ATP binding, we show that the K133A protein binds ATP, but with an affinity approximately 100-fold lower than that of wild-type Rad51. Our data suggest that ATP binding and release without hydrolysis by the K133A protein act as a mechanistic surrogate in a catalytic process that applies to all RecA-like recombinases. ATP binding promotes assembly and stabilization of a catalytically active nucleoprotein filament, while ATP hydrolysis promotes filament disassembly and release from DNA.     

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

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