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.     

Structure of human thymidylate synthase suggests advantages of chemotherapy with noncompetitive inhibitors

Thymidylate synthase (TS) is a major target in the chemotherapy of colorectal cancer and some other neoplasms. The emergence of resistance to the treatment is often related to the increased levels of TS in cancer cells, which have been linked to the elimination of TS binding to its own mRNA upon drug binding, a feedback regulatory mechanism, and/or to the increased stability to intracellular degradation of TS.drug complexes (versus unliganded TS). The active site loop of human TS (hTS) has a unique conformation resulted from a rotation by 180 degrees relative to its orientation in bacterial TSs. In this conformation, the enzyme must be inactive, because the catalytic cysteine is no longer positioned in the ligand-binding pocket. The ordered solvent structure obtained from high resolution crystallographic data (2.0 A) suggests that the inactive loop conformation promotes mRNA binding and intracellular degradation of the enzyme. This hypothesis is supported by fluorescence studies, which indicate that in solution both active and inactive forms of hTS are present. The binding of phosphate ion shifts the equilibrium toward the inactive conformation; subsequent dUMP binding reverses the equilibrium toward the active form. Thus, TS inhibition via stabilization of the inactive conformation should lead to less resistance than is observed with presently used drugs, which are analogs of its substrates, dUMP and CH(2)H(4)folate, and bind in the active site, promoting the active conformation. The presence of an extension at the N terminus of native hTS has no significant effect on kinetic properties or crystal structure.     

The R163K mutant of human thymidylate synthase is stabilized in an active conformation: structural asymmetry and reactivity of cysteine 195

Loop 181-197 of human thymidylate synthase (hTS) populates two conformational states. In the first state, Cys195, a residue crucial for catalytic activity, is in the active site (active conformer); in the other conformation, it is about 10 A away, outside the active site (inactive conformer). We have designed and expressed an hTS variant, R163K, in which the inactive conformation is destabilized. The activity of this mutant is 33% higher than that of wt hTS, suggesting that at least one-third of hTS populates the inactive conformer. Crystal structures of R163K in two different crystal forms, with six and two subunits per asymmetric part of the unit cells, have been determined. All subunits of this mutant are in the active conformation while wt hTS crystallizes as the inactive conformer in similar mother liquors. The structures show differences in the environment of catalytic Cys195, which correlate with Cys195 thiol reactivity, as judged by its oxidation state. Calculations show that the molecular electrostatic potential at Cys195 differs between the subunits of the dimer. One of the dimers is asymmetric with a phosphate ion bound in only one of the subunits. In the absence of the phosphate ion, that is in the inhibitor-free enzyme, the tip of loop 47-53 is about 11 A away from the active site.     

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

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

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.     

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.     

Analysis of mRNA recognition by human thymidylate synthase

Expression of hTS (human thymidylate synthase), a key enzyme in thymidine biosynthesis, is regulated on the translational level through a feedback mechanism that is rarely found in eukaryotes. At low substrate concentrations, the ligand-free enzyme binds to its own mRNA and stabilizes a hairpin structure that sequesters the start codon. When in complex with dUMP (2′-deoxyuridine-5′-monophosphate) and a THF (tetrahydrofolate) cofactor, the enzyme adopts a conformation that is unable to bind and repress expression of mRNA. Here, we have used a combination of X-ray crystallography, RNA mutagenesis and site-specific cross-linking studies to investigate the molecular recognition of TS mRNA by the hTS enzyme. The interacting mRNA region was narrowed to the start codon and immediately flanking sequences. In the hTS enzyme, a helix–loop–helix domain on the protein surface was identified as the putative RNA-binding site.     

Evolution of Metamorphism in Thymidylate Synthases Within the Primate Lineages

Crystal structures of human thymidylate synthase (hTS) revealed that the protein exists in active and inactive conformations, defined by the position of a loop containing the active site nucleophile. TS is highly homologous among diverse species; however, the residue at position 163 (hTS) differs among species. Arginine at this position is predicted by structural modeling to enable conformational switching. Arginine or lysine is reported at this position in all mammals in the GenBank and Ensembl databases, with arginine reported in only primates. Sequence analysis of the TS gene of representative primates revealed that arginine occurs at this relative position in all primates except a representative of prosimians. Mutant human proteins were created with residues at position 163 that occur in TSs from prokaryotes and eukaryotes. Catalytic constants (k _cat) of mutant enzymes were 45–149% of hTS, with the lysine mutant (R163K) exhibiting the highest k _cat. The effect of lysine substitution on solution structure and on ligand binding was investigated. R163K exhibited higher intrinsic fluorescence, a more negative molar ellipticity, and higher dissociation constants (K _d) for ligands that modulate protein conformation than hTS. Temperature effects on intrinsic fluorescence and catalytic activity of hTS and R163K are consistent with proteins populating different conformational states. The data indicate that the enzyme with arginine at the position corresponding to 163 (hTS) evolved after the divergence of prosimians and simians and that substitution of lysine by arginine confers unique structural and functional properties to the enzyme expressed in simian primates.     

The role of protein dynamics in thymidylate synthase catalysis: variants of conserved 2'-deoxyuridine 5'-monophosphate (dUMP)-binding Tyr-261

The enzyme thymidylate synthase (TS) catalyzes the reductive methylation of 2'-deoxyuridine 5'-monophosphate (dUMP) to 2'-deoxythymidine 5'-monophosphate. Using kinetic and X-ray crystallography experiments, we have examined the role of the highly conserved Tyr-261 in the catalytic mechanism of TS. While Tyr-261 is distant from the site of methyl transfer, mutants at this position show a marked decrease in enzymatic activity. Given that Tyr-261 forms a hydrogen bond with the dUMP 3'-O, we hypothesized that this interaction would be important for substrate binding, orientation, and specificity. Our results, surprisingly, show that Tyr-261 contributes little to these features of the mechanism of TS. However, the residue is part of the structural core of closed ternary complexes of TS, and conservation of the size and shape of the Tyr side chain is essential for maintaining wild-type values of kcat/Km. Moderate increases in Km values for both the substrate and cofactor upon mutation of Tyr-261 arise mainly from destabilization of the active conformation of a loop containing a dUMP-binding arginine. Besides binding dUMP, this loop has a key role in stabilizing the closed conformation of the enzyme and in shielding the active site from the bulk solvent during catalysis. Changes to atomic vibrations in crystals of a ternary complex of Escherichia coli Tyr261Trp are associated with a greater than 2000-fold drop in kcat/Km. These results underline the important contribution of dynamics to catalysis in TS.     

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

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

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

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

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.     

Effects of protonation state of Asp181 and position of active site water molecules on the conformation of PTP1B

In protein tyrosine phosphatase 1B (PTP1B), the flexible WPD loop adopts a closed conformation (WPD_closed) in the active state of PTP1B, bringing the catalytic Asp181 close to the active site pocket, while WPD loop is in an open conformation (WPD_open) in the inactive state. Previous studies showed that Asp181 may be protonated at physiological pH, and ordered water molecules exist in the active site. In the current study, molecular dynamics simulations are employed at different Asp181 protonation states and initial positions of active site water molecules, and compared with the existing crystallographic data of PTP1B. In WPD_closed conformation, the active site is found to maintain its conformation only in the protonated state of Asp181 in both free and liganded states, while Asp181 is likely to be deprotonated in WPD_open conformation. When the active site water molecule network that is a part of the free WPD_closed crystal structure is disrupted, intermediate WPD loop conformations, similar to that in the PTPRR crystal structure, are sampled in the MD simulations. In liganded PTP1B, one active site water molecule is found to be important for facilitating the orientation of Cys215 and the phosphate ion, thus may play a role in the reaction. In conclusion, conformational stability of WPD loop, and possibly catalytic activity of PTP1B, is significantly affected by the protonation state of Asp181 and position of active site water molecules, showing that these aspects should be taken into consideration both in MD simulations and inhibitor design. © Proteins 2013. © 2012 Wiley Periodicals, Inc.     

Mechanism of influence of phosphorylation on serine 124 on a decrease of catalytic activity of human thymidylate synthase

Regulation by phosphorylation is a well-established mechanism for controlling biological activity of proteins. Recently, phosphorylation of serine 124 in human thymidylate synthase (hTS) has been shown to lower the catalytic activity of the enzyme. To clarify a possible mechanism of the observed influence, molecular dynamics (MD), essential dynamics (ED) and MM-GBSA studies were undertaken. Structures derived from the MD trajectories reveal incorrect binding alignment between the pyrimidine ring of the substrate, dUMP, and the pterine ring of the cofactor analogue, THF, in the active site of the phosphorylated enzyme. The ED analysis indicates changes in the behavior of collective motions in the phosphorylated enzyme, suggesting that the formation of the closed ternary complex is hindered. Computed free energies, in agreement with structural analysis, predict that the binding of dUMP and THF to hTS is favored in the native compared to phosphorylated state of the enzyme. The paper describes at the structural level how phosphorylation at the distant site influences the ligand binding. We propose that the ‘phosphorylation effect’ is transmitted from the outside loop of Ser 124 into the active site via a subtle mechanism initiated by the long-range electrostatic repulsion between the phosphate groups of dUMP and Ser124. The mechanism can be described in terms of the interplay between the two groups of amino acids: the link (residues 125–134) and the patch (residues 189–192), resulting in the change of orientation of the pyrimidine ring of dUMP, which, in turn, prevents the correct alignment between the latter ring and the pterin ring of THF.     

Crystal structure of a deletion mutant of human thymidylate synthase Delta (7-29) and its ternary complex with Tomudex and dUMP

The crystal structures of a deletion mutant of human thymidylate synthase (TS) and its ternary complex with dUMP and Tomudex have been determined at 2.0 A and 2.5 A resolution, respectively. The mutant TS, which lacks 23 residues near the amino terminus, is as active as the wild-type enzyme. The ternary complex is observed in the open conformation, similar to that of the free enzyme and to that of the ternary complex of rat TS with the same ligands. This is in contrast to Escherichia coli TS, where the ternary complex with Tomudex and dUMP is observed in the closed conformation. While the ligands interact with each other in identical fashion regardless of the enzyme conformation, they are displaced by about 1.0 A away from the catalytic cysteine in the open conformation. As a result, the covalent bond between the catalytic cysteine sulfhydryl and the base of dUMP, which is the first step in the reaction mechanism of TS and is observed in all ternary complexes of the E. coli enzyme, is not formed. This displacement results from differences in the interactions between Tomudex and the protein that are caused by differences in the environment of the glutamyl tail of the Tomudex molecule. Despite the absence of the closed conformation, Tomudex inhibits human TS ten-fold more strongly than E. coli TS. These results suggest that formation of a covalent bond between the catalytic cysteine and the substrate dUMP is not required for effective inhibition of human TS by cofactor analogs and could have implications for drug design by eliminating this as a condition for lead compounds.     

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.     

Characterization of a polyclonal antibody to human thymidylate synthase suitable for the study of colorectal cancer specimens.

Measurement of thymidylate synthase (hTS) using immunohistochemical techniques has been reported in several clinical studies. However, its value as a prognostic indicator is still not clear. To pursue this, we have developed a new rabbit polyclonal antibody, hTS7.4. The antigen was recombinant hTS containing an N-terminal His(6)-tag. Antiserum hTS7.4 detected recombinant hTS by ELISA at a titer of 1:100,000. Western blot analysis of several human cell lines showed a single band of the expected 36-kD molecular size. HeLa cells treated with the TS inhibitor 5-FUdR showed the expected additional band corresponding to the ternary complex of hTS-dFUMP-reduced folate. hTS7.4 detected TS in bacterial, rat, mouse, and monkey cell extracts, and hTS8.3 (a closely related antiserum) immunoprecipitated a 36-kD [(35)S]-methionine-labeled protein from HeLa extracts. TS was detectable by indirect immunofluorescence in HeLa cells. Proliferating normal human fibroblasts in culture showed staining, but nonproliferating cells did not. Lymphocytes in the germinal center of human tonsil tissue, which are known to be proliferating, stained with hTS7.4 and also with monoclonal antibody TS106. TS may therefore be useful as an immunohistochemical marker of cell proliferation. Normal colon mucosa showed weak staining, whereas some colorectal cancer specimens stained very strongly with hTS7.4. A clinical study of colorectal cancer using this antibody is in progress. (J Histochem Cytochem 47:1563-1573, 1999)     

Regulation of dCTP deaminase from Escherichia coli by nonallosteric dTTP binding to an inactive form of the enzyme

The trimeric dCTP deaminase produces dUTP that is hydrolysed to dUMP by the structurally closely related dUTPase. This pathway provides 70-80% of the total dUMP as a precursor for dTTP. Accordingly, dCTP deaminase is regulated by dTTP, which increases the substrate concentration for half-maximal activity and the cooperativity of dCTP saturation. Likewise, increasing concentrations of dCTP increase the cooperativity of dTTP inhibition. Previous structural studies showed that the complexes of inactive mutant protein, E138A, with dUTP or dCTP bound, and wild-type enzyme with dUTP bound were all highly similar and characterized by having an ordered C-terminal. When comparing with a new structure in which dTTP is bound to the active site of E138A, the region between Val120 and His125 was found to be in a new conformation. This and the previous conformation were mutually exclusive within the trimer. Also, the dCTP complex of the inactive H121A was found to have residues 120-125 in this new conformation, indicating that it renders the enzyme inactive. The C-terminal fold was found to be disordered for both new complexes. We suggest that the cooperative kinetics are imposed by a dTTP-dependent lag of product formation observed in presteady-state kinetics. This lag may be derived from a slow equilibration between an inactive and an active conformation of dCTP deaminase represented by the dTTP complex and the dUTP/dCTP complex, respectively. The dCTP deaminase then resembles a simple concerted system subjected to effector binding, but without the use of an allosteric site.     

Role of a Novel PH-Kinase Domain Interface in PKB/Akt Regulation: Structural Mechanism for Allosteric Inhibition

Protein kinase B (PKB/Akt) belongs to the AGC superfamily of related serine/threonine protein kinases. It is a key regulator downstream of various growth factors and hormones and is involved in malignant transformation and chemo-resistance. Full-length PKB protein has not been crystallised, thus studying the molecular mechanisms that are involved in its regulation in relation to its structure have not been simple. Recently, the dynamics between the inactive and active conformer at the molecular level have been described. The maintenance of PKB''s inactive state via the interaction of the PH and kinase domains prevents its activation loop to be phosphorylated by its upstream activator, phosphoinositide-dependent protein kinase-1 (PDK1). By using a multidisciplinary approach including molecular modelling, classical biochemical assays, and Förster resonance energy transfer (FRET)/two-photon fluorescence lifetime imaging microscopy (FLIM), a detailed model depicting the interaction between the different domains of PKB in its inactive conformation was demonstrated. These findings in turn clarified the molecular mechanism of PKB inhibition by AKT inhibitor VIII (a specific allosteric inhibitor) and illustrated at the molecular level its selectivity towards different PKB isoforms. Furthermore, these findings allude to the possible function of the C-terminus in sustaining the inactive conformer of PKB. This study presents essential insights into the quaternary structure of PKB in its inactive conformation. An understanding of PKB structure in relation to its function is critical for elucidating its mode of activation and discovering how to modulate its activity. The molecular mechanism of inhibition of PKB activation by the specific drug AKT inhibitor VIII has critical implications for determining the mechanism of inhibition of other allosteric inhibitors and for opening up opportunities for the design of new generations of modulator drugs.     

ortho-Halogen naphthaleins as specific inhibitors of Lactobacillus casei thymidylate synthase. Conformational properties and biological activity

Thymidylate synthase (TS) (EC 2.1.1.45), an enzyme involved in the DNA synthesis of both prokaryotic and eukaryotic cells, is a potential target for the development of anticancer and antinfective agents. Recently, we described a series of phthalein and naphthalein derivatives as TS inhibitors. These compounds have structures unrelated to the folate (Non-Analogue Antifolate Inhibitors, NAAIs) and were selective for the bacterial versus the human TS (hTS). In particular, halogen-substituted molecules were the most interesting. In the present paper the halogen derivatives of variously substituted 3,3-bis(4-hydroxyphenyl)-1H,3H-naphtho[2,3-c]furan-1-one (1-5) and 3,3-bis(4-hydroxyphenyl)-1H,3H-naphtho[1,8-c,d]pyran-1-one (6-14) were synthesized to investigate the biological effect of halogen substitution on the inhibition and selectivity for the TS enzymes. Conformational properties of the naphthalein series were explored in order to highlight possible differences between molecules that show species-specific biological profile with respect to non species-specific ones. With this aim, the conformational properties of the synthesized compounds were investigated by NMR, in various solvents and at different temperatures, and by computational analysis. The apparent inhibition constants (K(i)) for Lactobacillus casei TS (LcTS) were found to range from 0.7 to 7.0 microM, with the exception of the weakly active iodo-derivatives (4, 10, 13); all] the compounds were poorly active against hTS. The di-halogenated compounds 7, 8, 14 showed the highest specificity towards LcTS, their specificity index (SI) ranging between 40 and >558. The di-halogenated 1,8-naphthalein derivatives (7-10) exhibited different conformational properties with respect to the tetra-haloderivatives. Though a clear explanation for the observed specificity by means of conformational analysis is difficult to find, some interesting conformational effects are discussed in the context of selective recognition of the compounds investigated by the LcTS enzyme.