Joseph Yanchunas scite author profile

The inhibition of DPP-IV by saxagliptin has been proposed to occur through formation of a covalent but reversible complex. To evaluate further the mechanism of inhibition, we determined the X-ray crystal structure of the DPP-IV:saxagliptin complex. This structure reveals covalent attachment between S630 and the inhibitor nitrile carbon (C-O distance <1.3 Å ). To investigate whether this serine addition is assisted by the catalytic His-Asp dyad, we generated two mutants of DPP-IV, S630A and H740Q, and assayed them for ability to bind inhibitor. DPP-IV H740Q bound saxagliptin with an ;1000-fold reduction in affinity relative to DPP-IV WT , while DPP-IV S630A showed no evidence for binding inhibitor. An analog of saxagliptin lacking the nitrile group showed unchanged binding properties to the both mutant proteins, highlighting the essential role S630 and H740 play in covalent bond formation between S630 and saxagliptin. Further supporting mechanism-based inhibition by saxagliptin, NMR spectra of enzyme-saxagliptin complexes revealed the presence of three downfield resonances with low fractionation factors characteristic of short and strong hydrogen bonds (SSHB). Comparison of the NMR spectra of various wild-type and mutant DPP-IV:ligand complexes enabled assignment of a resonance at ;14 ppm to H740. Two additional DPP-IV mutants, Y547F and Y547Q, generated to probe potential stabilization of the enzyme-inhibitor complex by this residue, did not show any differences in inhibitor binding either by ITC or NMR. Together with the previously published enzymatic data, the structural and binding data presented here strongly support a histidine-assisted covalent bond formation between S630 hydroxyl oxygen and the nitrile group of saxagliptin.Keywords: DPP-IV; X-ray crystal structure; mutant; ITC; proton NMR; short, strong hydrogen bond; serine protease; saxagliptin Dipeptidyl peptidase IV is a serine protease that modulates the biological activity of specific circulating peptide hormones, chemokines, cytokines, and neuropeptides Abbreviations: ANS, 1-anilino-8-naphthalene sulfonate; DPP-IV, dipeptidyl peptidase IV; GLP-1, glucagon-like peptide-1; ITC, isothermal titration calorimetry; pNA, p-nitroaniline; P n -P n9 , amino acid residues of the substrate which numerically indicate the position relatively to the scissile bond, n being the residues toward the N terminus and n9 being the residues toward the C terminus (this nomenclature was first defined by Schechter and Berger [1967]); SEC-MALS, size-exclusion chromatography-multiple angle light scattering; SKIE, solvent kinetic isotope effect; SSHB, short strong hydrogen bond; SIHB, short ionic hydrogen bond; TSE, thermal stability enhancement.Article and publication are at http://www.proteinscience.org/cgi

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Steady-State Kinetic Mechanism of Escherichia coli UDP-N-Acetylenolpyruvylglucosamine Reductase

Dhalla¹,

Yanchunas²,

Ho³

et al. 1995

Biochemistry

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The Escherichia coli MurB gene encoding UDP-N-acetylenolpyruvylglucosamine reductase was expressed to a level of approximately 100 mg/L as a fusion construct with maltose binding protein. Rapid affinity purification, proteolysis, and anion exchange chromatography yielded homogeneous enzyme containing 1 mol/mol bound FAD. Enzyme was maximally activated by K+, NH4+, and Rb+ at cation concentrations between 10 and 50 mM. Steady-state enzyme kinetics at pH 8.0 and 37 degrees C revealed weak and strong substrate inhibition by NADPH and UDP-N-acetylenolpyruvylglucosamine, respectively, where the KiS were 910 microM and 73 microM. Substrate inhibition was pH dependent for both substrates. Initial velocity measurements as a function of both substrates produced patterns consistent with a ping pong bi bi double competitive substrate inhibition mechanism. Data at pH 8.0 yielded kinetic constants corresponding to Km,UNAGEP = 24 +/- 3 microM, Ki,UNAGEP = 73 +/- 19 microM, Km,NADPH = 17 +/- 3 microM, Ki,NADPH = 910 +/- 670 microM, and kcat = 62 +/- 3 s-1. A slow anaerobic exchange reaction with thio-NADP+ provided evidence for release of NADP+ in the absence of UNAGEP. Alternate reduced nicotinamide dinucleotides, including NHXDPH, 3'-NADPH, and alpha-NADPH, were substrates, whereas NADH was not. Several nucleotides, including ADP and UDP, were weak inhibitors of the enzyme with inhibition constants between 5 and 97 mM. Various analogs of NADP+, including 3'-NADP+, thio-NADP+, APADP+, NEthDP+, and NHXDP+, were inhibitors of the enzyme with respect to NADPH and yielded inhibition constants in the range of 110-1100 microM. Analogs without the 2'- or 3'-phosphate of NADPH or NADP+ were not substrates or inhibitors. Double inhibition experiments with varied APADP+ and UNAG produced inhibition patterns consistent with mutually exclusive inhibitor binding. The data suggest that NADPH and UNAGEP share a subsite that prevents both molecules from binding at once.

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Correlation of High-Throughput Pregnane X Receptor (PXR) Transactivation and Binding Assays

Zhu

Kim²,

Chen

et al. 2004

SLAS Discovery

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Pregnane X receptor (PXR) transactivation and binding assays have been developed into high-throughput assays, which are robust and reproducible (Z′ > 0.5). For most compounds, there was a good correlation between the results of the transactivation and binding assays. EC 50 values of compounds in the transactivation assay correlated reasonably well with their IC 50 values in the binding assay. However, there were discrepancies with some compounds showing high binding affinity in the binding assay translated into low transactivation. The most likely cause for these discrepancies was an agonistdependent relationship between binding affinity and transactivation response. In general, compounds that bound to human PXR and transactivated PXR tended to be large hydrophobic molecules. (Journal of Biomolecular Screening 2004:533-540)

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Evaluation of the Kinetic Mechanism of Escherichia coli Uridine Diphosphate-N-acetylmuramate:l-Alanine Ligase

Emanuele

Yanchunas

et al. 1997

Biochemistry

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Initial velocity methods were used to probe the kinetic mechanism of Escherichia coli uridine diphosphate-N-acetylmuramate:L-alanine ligase (UNAM:L-Ala ligase). When the activity (in the forward direction) versus substrate concentration data were plotted in double-reciprocal form, all line patterns were intersecting. The best fit of these data was to the equation for an ordered mechanism with the following parameters: k(cat), 1000 +/- 100 min(-1); Kma, 210 +/- 40 microM; Kmb, 84 +/- 20 microM; Kmc, 70 +/- 15 microM; Kia, 180 +/- 50 microM; Kib, 68 +/- 24 microM. Initial velocity line patterns were also determined when the concentration of one substrate was varied at different fixed concentrations of a second substrate while the third substrate was held at a concentration more than 100 times its Km value. Reciprocal plots of data collected with either ATP or L-alanine present at more than 100 times their Km values resulted in intersecting line patterns. Data collected with UNAM present at 100 times its Km value gave a set of parallel lines. These data are consistent with UNAM binding as the second substrate in an ordered mechanism. ADP, uridine diphosphate-N-acetylmuramoyl-L-alanine (UNAMA), and phosphate were tested as product inhibitors versus substrates. None of the products were competitive inhibitors versus L-alanine or UNAM, while the only observed competitive inhibition was ADP versus ATP. These results are consistent with an ordered kinetic mechanism wherein ATP binds first, UNAM binds second, and ADP is the last product released. Rapid quench experiments were performed in the presence of all three substrates or in the presence of ATP and UNAM. The production of acid-labile phosphate as a function of time is characterized by a burst phase followed by a slower linear phase with the rate close to k(cat) in the presence of all three substrates. Only a burst phase was observed for the time course of the reaction in the presence of ATP and UNAM. In both cases, the burst rate was identical. These observations are consistent with L-alanine being the third substrate to bind in a sequential mechanism involving a putative acyl-phosphate intermediate.

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