1v2q Citations

Understanding protein-ligand interactions: the price of protein flexibility.

Rauh D, Klebe G, Stubbs MT
J Mol Biol 335 1325-41 (2004)
Related entries: 1v2j, 1v2k, 1v2l, 1v2m, 1v2n, 1v2o, 1v2p, 1v2r, 1v2s, 1v2t, 1v2u, 1v2v, 1v2w

Cited: 34 times
EuropePMC logo PMID: 14729347

Abstract

In order to design selective, high-affinity ligands to a target protein, it is advantageous to understand the structural determinants for protein-ligand complex formation at the atomic level. In a model system, we have successively mapped the factor Xa binding site onto trypsin, showing that certain mutations influence both protein structure and inhibitor specificity. Our previous studies have shown that introduction of the 172SSFI175 sequence of factor Xa into rat or bovine trypsin results in the destabilisation of the intermediate helix with burial of Phe174 (the down conformation). Surface exposure of the latter residue (the up conformation) is critical for the correct formation of the aromatic box found in factor Xa-ligand complexes. In the present study, we investigate the influence of aromatic residues in position 174. Replacement with the bulky tryptophan (SSWI) shows reduced affinity for benzamidine-based inhibitors (1) and (4), whereas removal of the side-chain (alanine, SSAI) or exchange with a hydrophilic residue (arginine, SSRI) leads to a significant loss in affinity for all inhibitors studied. The variants could be crystallised in the presence of different inhibitors in multiple crystal forms. Structural characterisation of the variants revealed three different conformations of the intermediate helix and 175 loop in SSAI (down, up and super-up), as well as a complete disorder of this region in one crystal form of SSRI, suggesting that the compromised affinity of these variants is related to conformational flexibility. The influence of Glu217, peripheral to the ligand-binding site in factor Xa, was investigated. Introduction of Glu217 into trypsin variants containing the SSFI sequence exhibited enhanced affinity for the factor Xa ligands (2) and (3). The crystal structures of these variants also exhibited the down and super-up conformations, the latter of which could be converted to up upon soaking and binding of inhibitor (2). The improved affinity of the Glu217-containing variants appears to be due to a shift towards the up conformation. Thus, the reduction in affinity caused by conformational variability of the protein target can be partially or wholly offset by compensatory binding to the up conformation. The insights provided by these studies will be helpful in improving our understanding of ligand binding for the drug design process.

Articles - 1v2q mentioned but not cited (5)

  1. PocketMatch: a new algorithm to compare binding sites in protein structures. Yeturu K, Chandra N. BMC Bioinformatics 9 543 (2008)
  2. Pharmacophore-based similarity scoring for DOCK. Jiang L, Rizzo RC. J Phys Chem B 119 1083-1102 (2015)
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Reviews citing this publication (1)

  1. Determinants of specificity in coagulation proteases. Page MJ, Macgillivray RT, Di Cera E. J Thromb Haemost 3 2401-2408 (2005)

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  1. Incorporation of protein flexibility and conformational energy penalties in docking screens to improve ligand discovery. Fischer M, Coleman RG, Fraser JS, Shoichet BK. Nat Chem 6 575-583 (2014)
  2. Biochemical and structural analysis of substrate promiscuity in plant Mg2+-dependent O-methyltransferases. Kopycki JG, Rauh D, Chumanevich AA, Neumann P, Vogt T, Stubbs MT. J Mol Biol 378 154-164 (2008)
  3. Use of spectroscopic, zeta potential and molecular dynamic techniques to study the interaction between human holo-transferrin and two antagonist drugs: comparison of binary and ternary systems. Kabiri M, Amiri-Tehranizadeh Z, Baratian A, Saberi MR, Chamani J. Molecules 17 3114-3147 (2012)
  4. Conserved conformational selection mechanism of Hsp70 chaperone-substrate interactions. Sekhar A, Velyvis A, Zoltsman G, Rosenzweig R, Bouvignies G, Kay LE. Elife 7 e32764 (2018)
  5. Homologous ligands accommodated by discrete conformations of a buried cavity. Merski M, Fischer M, Balius TE, Eidam O, Shoichet BK. Proc Natl Acad Sci U S A 112 5039-5044 (2015)
  6. Observed bromodomain flexibility reveals histone peptide- and small molecule ligand-compatible forms of ATAD2. Poncet-Montange G, Zhan Y, Bardenhagen JP, Petrocchi A, Leo E, Shi X, Lee GR, Leonard PG, Geck Do MK, Cardozo MG, Andersen JN, Palmer WS, Jones P, Ladbury JE. Biochem J 466 337-346 (2015)
  7. Merging the binding sites of aldose and aldehyde reductase for detection of inhibitor selectivity-determining features. Steuber H, Heine A, Podjarny A, Klebe G. J Mol Biol 379 991-1016 (2008)
  8. Conformational variability of benzamidinium-based inhibitors. Li X, He X, Wang B, Merz K. J Am Chem Soc 131 7742-7754 (2009)
  9. The price of flexibility - a case study on septanoses as pyranose mimetics. Sager CP, Fiege B, Zihlmann P, Vannam R, Rabbani S, Jakob RP, Preston RC, Zalewski A, Maier T, Peczuh MW, Ernst B. Chem Sci 9 646-654 (2018)
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  11. Engineering protein allostery: 1.05 A resolution structure and enzymatic properties of a Na+-activated trypsin. Page MJ, Carrell CJ, Di Cera E. J Mol Biol 378 666-672 (2008)
  12. Investigation of the interactions of quercetin and morin with trypsin. Zhang HM, Wang YQ, Zhou QH. Luminescence 24 355-362 (2009)
  13. Optimal strategies for virtual screening of induced-fit and flexible target in the 2015 D3R Grand Challenge. Ye Z, Baumgartner MP, Wingert BM, Camacho CJ. J Comput Aided Mol Des 30 695-706 (2016)
  14. Discovery of new MurA inhibitors using induced-fit simulation and docking. Rožman K, Lešnik S, Brus B, Hrast M, Sova M, Patin D, Barreteau H, Konc J, Janežič D, Gobec S. Bioorg Med Chem Lett 27 944-949 (2017)
  15. Understanding binding selectivity toward trypsin and factor Xa: the role of aromatic interactions. Di Fenza A, Heine A, Koert U, Klebe G. ChemMedChem 2 297-308 (2007)
  16. A proline to glycine mutation in the Lck SH3-domain affects conformational sampling and increases ligand binding affinity. Bauer F, Sticht H. FEBS Lett 581 1555-1560 (2007)
  17. Impact of protein and ligand impurities on ITC-derived protein-ligand thermodynamics. Grüner S, Neeb M, Barandun LJ, Sielaff F, Hohn C, Kojima S, Steinmetzer T, Diederich F, Klebe G. Biochim Biophys Acta 1840 2843-2850 (2014)
  18. Variation of protein binding cavity volume and ligand volume in protein-ligand complexes. Saranya N, Selvaraj S. Bioorg Med Chem Lett 19 5769-5772 (2009)
  19. Evaluation of docking performance in a blinded virtual screening of fragment-like trypsin inhibitors. Surpateanu G, Iorga BI. J Comput Aided Mol Des 26 595-601 (2012)
  20. Combinatorial enzyme design probes allostery and cooperativity in the trypsin fold. Page MJ, Di Cera E. J Mol Biol 399 306-319 (2010)
  21. Protein-ligand binding detected using ultrafiltration Raman difference spectroscopy. Xie Y, Zhang D, Ben-Amotz D. Anal Biochem 373 154-160 (2008)
  22. Two Methods, One Goal: Structural Differences between Cocrystallization and Crystal Soaking to Discover Ligand Binding Poses. Wienen-Schmidt B, Oebbeke M, Ngo K, Heine A, Klebe G. ChemMedChem 16 292-300 (2021)
  23. Classification and comparison of ligand-binding sites derived from grid-mapped knowledge-based potentials. Hoppe C, Steinbeck C, Wohlfahrt G. J Mol Graph Model 24 328-340 (2006)
  24. An Improved Receptor-Based Pharmacophore Generation Algorithm Guided by Atomic Chemical Characteristics and Hybridization Types. He G, Gong B, Li J, Song Y, Li S, Lu X. Front Pharmacol 9 1463 (2018)
  25. Prodrug-based design, synthesis, and biological evaluation of N-benzenesulfonylpiperidine derivatives as novel, orally active factor Xa inhibitors. Ishihara T, Seki N, Hirayama F, Orita M, Koshio H, Taniuchi Y, Sakai-Moritani Y, Iwatsuki Y, Kaku S, Kawasaki T, Matsumoto Y, Tsukamoto S. Bioorg Med Chem 15 4175-4192 (2007)
  26. Molecular dynamics simulations of Factor Xa: insight into conformational transition of its binding subsites. Singh N, Briggs JM. Biopolymers 89 1104-1113 (2008)
  27. Towards a restriction proteinase: construction of a self-activating enzyme. Schöpfel M, Tziridis A, Arnold U, Stubbs MT. Chembiochem 12 1523-1527 (2011)
  28. Trio-pharmacophore DNA-encoded chemical library for simultaneous selection of fragments and linkers. Cui M, Nguyen D, Gaillez MP, Heiden S, Lin W, Thompson M, Reddavide FV, Chen Q, Zhang Y. Nat Commun 14 1481 (2023)


Related citations provided by authors (5)

  1. ZZ made EZ: influence of inhibitor configuration on enzyme selectivity.. Rauh D, Klebe G, Sturzebecher J, Stubbs MT J. Mol. Biol. 330 761-770 (2003)
  2. Trypsin mutants for structure-based drug design: expression, refolding and crystallisation.. Rauh D, Reyda S, Klebe G, Stubbs MT Biol. Chem. 383 1309-1314 (2002)
  3. Reconstructing the Binding Site of Factor Xa in Trypsin Reveals Ligand-Induced Structural Plasticity.. Reyda S, Sohn C, Klebe G, Rall K, Ullmann D, Jakubke HD, Stubbs MT J. Mol. Biol. 325 963-977 (2003)
  4. pH-dependent binding modes observed in trypsin crystals: lessons for structure-based drug design.. Stubbs MT, Reyda S, Dullweber F, Moller M, Klebe G, Dorsch D, Mederski WW, Wurziger H Chembiochem 3 246-249 (2002)
  5. Structural and functional analyses of benzamidine-based inhibitors in complex with trypsin: implications for the inhibition of factor Xa, tPA, and urokinase.. Renatus M, Bode W, Huber R, Sturzebecher J, Stubbs MT J. Med. Chem. 41 5445-5456 (1998)

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