1epm Citations

A structural comparison of 21 inhibitor complexes of the aspartic proteinase from Endothia parasitica.

Bailey D, Cooper JB
Protein Sci 3 2129-43 (1994)
Related entries: 1epl, 1epn, 1epr

Cited: 18 times
EuropePMC logo PMID: 7703859

Abstract

The aspartic proteinases are an important family of enzymes associated with several pathological conditions such as hypertension (renin), gastric ulcers (pepsin), neoplastic disease (cathepsins D and E), and AIDS (HIV proteinase). Studies of inhibitor binding are therefore of great importance for design of novel inhibitors for potential therapeutic applications. Numerous X-ray analyses have shown that transition-state isostere inhibitors of aspartic proteinases bind in similar extended conformations in the active-site cleft of the target enzyme. Upon comparison of 21 endothiapepsin inhibitor complexes, the hydrogen bond lengths were found to be shortest where the isostere (P1-P'1) interacts with the enzyme's catalytic aspartate pair. Hydrogen bonds with good geometry also occur at P'2, and more so at P3, where a conserved water molecule is involved in the interactions. Weaker interactions also occur at P2, where the side-chain conformations of the inhibitors appear to be more variable than at the more tightly held positions. At P2 and, to a lesser extent, P3, the side-chain conformations depend intriguingly on interactions with spatially adjacent side chains, namely P'1 and P1, respectively. The tight binding at P1-P'1, P3, and P'2 is also reflected in the larger number of van der Waals contacts and the large decreases in solvent-accessible area at these positions, as well as their low temperature factors. Our analysis substantiates earlier proposals for the locations of protons in the transition-state complex. Aspartate 32 is probably ionized in the complexes, its charge being stabilized by 1, or sometimes 2, hydrogen bonds from the transition-state analogues at P1. The detailed comparison also indicates that the P1 and P2 residues of substrate in the ES complex may be strained by the extensive binding interactions at P3, P'1, and P'2 in a manner that would facilitate hydrolysis of the scissile peptide bond.

Articles - 1epm mentioned but not cited (1)

  1. Finding evolutionary relations beyond superfamilies: fold-based superfamilies. Matsuda K, Nishioka T, Kinoshita K, Kawabata T, Go N. Protein Sci 12 2239-2251 (2003)


Articles citing this publication (17)

  1. Structural basis for inhibition of Aspergillus niger xylanase by triticum aestivum xylanase inhibitor-I. Sansen S, De Ranter CJ, Gebruers K, Brijs K, Courtin CM, Delcour JA, Rabijns A. J Biol Chem 279 36022-36028 (2004)
  2. The crystal structure of a major secreted aspartic proteinase from Candida albicans in complexes with two inhibitors. Cutfield SM, Dodson EJ, Anderson BF, Moody PC, Marshall CJ, Sullivan PA, Cutfield JF. Structure 3 1261-1271 (1995)
  3. Analysis of crystal structures of aspartic proteinases: on the role of amino acid residues adjacent to the catalytic site of pepsin-like enzymes. Andreeva NS, Rumsh LD. Protein Sci 10 2439-2450 (2001)
  4. Structure of a secreted aspartic protease from C. albicans complexed with a potent inhibitor: implications for the design of antifungal agents. Abad-Zapatero C, Goldman R, Muchmore SW, Hutchins C, Stewart K, Navaza J, Payne CD, Ray TL. Protein Sci 5 640-652 (1996)
  5. The catalytic mechanism of an aspartic proteinase explored with neutron and X-ray diffraction. Coates L, Tuan HF, Tomanicek S, Kovalevsky A, Mustyakimov M, Erskine P, Cooper J. J Am Chem Soc 130 7235-7237 (2008)
  6. Mapping the energetics of water-protein and water-ligand interactions with the "natural" HINT forcefield: predictive tools for characterizing the roles of water in biomolecules. Amadasi A, Spyrakis F, Cozzini P, Abraham DJ, Kellogg GE, Mozzarelli A. J Mol Biol 358 289-309 (2006)
  7. X-ray, neutron and NMR studies of the catalytic mechanism of aspartic proteinases. Coates L, Erskine PT, Mall S, Gill R, Wood SP, Myles DA, Cooper JB. Eur Biophys J 35 559-566 (2006)
  8. Dynamic ligand design and combinatorial optimization: designing inhibitors to endothiapepsin. Stultz CM, Karplus M. Proteins 40 258-289 (2000)
  9. Molecular cloning of an extracellular aspartic proteinase from Rhizopus microsporus and evidence for its expression during infection. Schoen C, Reichard U, Monod M, Kratzin HD, Rüchel R. Med Mycol 40 61-71 (2002)
  10. The crystal structure of the secreted aspartic protease 1 from Candida parapsilosis in complex with pepstatin A. Dostál J, Brynda J, Hrusková-Heidingsfeldová O, Sieglová I, Pichová I, Rezácová P. J Struct Biol 167 145-152 (2009)
  11. Atomic resolution analysis of the catalytic site of an aspartic proteinase and an unexpected mode of binding by short peptides. Erskine PT, Coates L, Mall S, Gill RS, Wood SP, Myles DA, Cooper JB. Protein Sci 12 1741-1749 (2003)
  12. An assessment of protein-ligand binding site polarizability. Nayeem A, Krystek S, Stouch T. Biopolymers 70 201-211 (2003)
  13. X-ray structures of five renin inhibitors bound to saccharopepsin: exploration of active-site specificity. Cronin NB, Badasso MO, J Tickle I, Dreyer T, Hoover DJ, Rosati RL, Humblet CC, Lunney EA, Cooper JB. J Mol Biol 303 745-760 (2000)
  14. Influence of conformation on the representation of small flexible molecules at low resolution: alignment of endothiapepsin ligands. Leherte L, Meurice N, Vercauteren DP. J Comput Aided Mol Des 19 525-549 (2005)
  15. Similarity measures based on Gaussian-type promolecular electron density models: alignment of small rigid molecules. Leherte L. J Comput Chem 27 1800-1816 (2006)
  16. Synthesis of α-carboxyphosphinopeptides derived from norleucine. Pícha J, Buděšínský M, Fiedler P, Sanda M, Jiráček J. Amino Acids 39 1265-1280 (2010)
  17. Single-column purification of syncephapepsin--an aspartic proteinase from Syncephalastrum racemosum. Ho HC, Shiau PF, Wu SL. Protein Expr Purif 12 399-403 (1998)


Related citations provided by authors (1)

  1. The 3D Structure at 2 Angstroms Resolution of Endothiapepsin. Blundell TL, Jenkins J, Sewell BT, Pearl LH, Cooper JB, Tickle IJ, Veerapandian B, Wood SP J. Mol. Biol. 211 919- (1990)

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