2'-Deoxyuridine 5'-monophosphate substrate displacement in thymidylate synthase through 6-hydroxy-2H-naphtho[1,8-bc]furan-2-one derivatives.

Thymidylate synthase (TS) is a target for antifolate-based chemotherapies of microbial and human diseases. Here, ligand-based, synthetic, and X-ray crystallography studies led to the discovery of 6-(3-cyanobenzoyloxy)-2-oxo-2H-naphto[1,8-bc]furan, a novel inhibitor with a Ki of 310 nM against Pneumocystis carinii TS. The X-ray ternary complex with Escherichia coli TS revealed, for the first time, displacement of the substrate toward the dimeric protein interface, thus providing new opportunities for further design of specific inhibitors of microbial pathogens.

Identification of the binding modes of N-phenylphthalimides inhibiting bacterial thymidylate synthase through X-ray crystallography screening.

To identify specific bacterial thymidylate synthase (TS) inhibitors, we exploited phenolphthalein (PTH), which inhibits both bacterial and human enzymes. The X-ray crystal structure of Lactobacillus casei TS (LcTS) that binds PTH showed multiple binding modes of the inhibitor, which prevented a classical structure-based drug design approach. To overcome this issue, we synthesized two phthalimidic libraries that were tested against TS enzymes and then we performed X-ray crystallographic screening of the active compounds. Compounds 6A, 8A, and 12A showed 40-fold higher affinity for bacterial TS than human TS. The X-ray crystallographic screening characterized the binding mode of six inhibitors in complexes with LcTS. Of these, 20A, 23A, and 24A showed a common unique binding mode, whereas 8A showed a different, unique binding mode. A comparative analysis of the LcTS X-ray complexes that were obtained with the pathogenic TS enabled the selection of compounds 8A and 23A as specific compounds and starting points to be exploited for the specific inhibition of pathogen enzymes.

Structural insights into the catalytic mechanism of the bacterial class B phosphatase AphA belonging to the DDDD superfamily of phosphohydrolases.

AphA is a magnesium-dependent, bacterial class B acid phosphatase that catalyzes the hydrolysis of a variety of phosphoester substrates and belongs to the DDDD superfamily of phosphohydrolases. The recently reported crystal structure of AphA from Escherichia coli has revealed the quaternary structure of the enzyme together with hints about its catalytic mechanism. The present work reports the crystal structures of AphA from E. coli in complex with substrate, transition-state, and intermediate analogues. The structures provide new insights into the mechanism of the enzyme and allow a revision of some aspects of the previously proposed mechanism that have broader implications for all the phosphatases of the DDDD superfamily.

Biochemical characterization of the class B acid phosphatase (AphA) of Escherichia coli MG1655.

The AphA enzyme of Escherichia coli, a molecular class B periplasmic phosphatase that belongs to the DDDD superfamily of phosphohydrolases, was purified and subjected to biochemical characterization. Kinetic analysis with several substrates revealed that the enzyme essentially behaves as a broad-spectrum nucleotidase highly active on 3'- and 5'-mononucleotides and monodeoxynucleotides, but not active on cyclic nucleotides, or nucleotides di- and triphosphate. Mononucleotides are degraded to nucleosides, and AphA apparently does not exhibit any nucleotide phosphomutase activity. However, it can transphosphorylate nucleosides in the presence of phosphate donors. Kinetic properties of AphA are consistent with structural data, and suggest a role for the hydrophobic pocket present in the active site crevice, made by residues Phe 56, Leu71, Trp77 and Tyr193, in conferring preferential substrate specificity by accommodating compounds with aromatic rings. AphA was inhibited by several chelating agents, including EDTA, EGTA, 1,10-phenanthroline and dipicolinic acid, with EDTA being apparently the most powerful inhibitor.

Molecular basis for the binding of competitive inhibitors of maize polyamine oxidase.

Maize polyamine oxidase (MPAO), the only member of the polyamine oxidase (PAO) family whose three-dimensional structure is known, is characterized by a 30 A long U-shaped catalytic tunnel located between the substrate binding domain and the FAD. To shed light on the MPAO ligand binding mode, we studied the inhibition properties of linear diamines, agmatine, prenylagmatine (G3), G3 analogues, and guazatine, and analyzed the structural determinants of their biological activity. Linear diamines competitively inhibited MPAO, with the inhibitory activity increasing as a function of the number of methylene groups. With regard to the guanidino competitive inhibitors, including agmatine, G3, and G3 analogues, the presence of a hydrophobic substituent constitutes the principal factor influencing MPAO inhibition, as the addition of a hydrophobic substituent to the guanidino group of both G3 and G3 analogues greatly increases the inhibitory activity. Moreover, results obtained by a molecular modeling procedure indicated that in their preferred orientation, G3 analogues point the ammonium group toward the narrow entrance of the tunnel, while the terminal hydrophobic group is located within the large entrance. The high binding affinity for MPAO exhibited by G3 and G3 analogues bearing a prenyl group as a substituent on the guanidino moiety is in agreement with the observation that the prenyl group binds in a well-defined hydrophobic pocket, mainly formed by aromatic residues. Finally, docking simulations performed with the charged and uncharged forms of MPAO inhibitors indicate that the stereoelectronic properties of the MPAO active site are consistent with the binding of inhibitors in the protonated form.