1rrh Citations

Effect of crystal freezing and small-molecule binding on internal cavity size in a large protein: X-ray and docking studies of lipoxygenase at ambient and low temperature at 2.0 A resolution.

Skrzypczak-Jankun E, Borbulevych OY, Zavodszky MI, Baranski MR, Padmanabhan K, Petricek V, Jankun J
Acta Crystallogr D Biol Crystallogr 62 766-75 (2006)
Cited: 12 times
EuropePMC logo PMID: 16790932

Abstract

Flash-freezing is a technique that is commonly used nowadays to collect diffraction data for X-ray structural analysis. It can affect both the crystal and molecular structure and the molecule's surface, as well as the internal cavities. X-ray structural data often serve as a template for the protein receptor in docking calculations. Thus, the size and shape of the binding site determines which small molecules could be found as potential ligands in silico, especially during high-throughput rigid docking. Data were analyzed for wild soybean lipoxygenase-3 (MW 97 kDa) at 293 and 93 K and compared with the results from studies of its molecular complexes with known inhibitors, structures published by others for a derivative of the same enzyme (98 K) or a topologically close isozyme lipoxygenase-1 (at ambient temperature and 100 K). Analysis of these data allows the following conclusions. (i) Very small changes in the relative orientation of the molecules in the crystal can cause major changes in the crystal reciprocal lattice. (ii) The volume of the internal cavities can ;shrink' by several percent upon freezing even when the unit-cell and the protein molecular volume show changes of only 1-2%. (iii) Using a receptor structure determined based on cryogenic data as a target for computational screening requires flexible docking to enable the expansion of the binding-site cavity and sampling of the alternative conformations of the crucial residues.

Articles - 1rrh mentioned but not cited (3)

  1. Early Antibody Lineage Diversification and Independent Limb Maturation Lead to Broad HIV-1 Neutralization Targeting the Env High-Mannose Patch. MacLeod DT, Choi NM, Briney B, Garces F, Ver LS, Landais E, Murrell B, Wrin T, Kilembe W, Liang CH, Ramos A, Bian CB, Wickramasinghe L, Kong L, Eren K, Wu CY, Wong CH, IAVI Protocol C Investigators & The IAVI African HIV Research Network, Kosakovsky Pond SL, Wilson IA, Burton DR, Poignard P. Immunity 44 1215-1226 (2016)
  2. Locating a lipid at the portal to the lipoxygenase active site. Gaffney BJ, Bradshaw MD, Frausto SD, Wu F, Freed JH, Borbat P. Biophys J 103 2134-2144 (2012)
  3. Arginine and Lysine interactions with π residues in metalloproteins. Anitha P, Sivasakthi V, Lavanya P, Bag S, Kumar KM, Anbarasu A, Ramaiah S. Bioinformation 8 820-826 (2012)


Articles citing this publication (9)

  1. Conformational flexibility in mammalian 15S-lipoxygenase: Reinterpretation of the crystallographic data. Choi J, Chon JK, Kim S, Shin W. Proteins 70 1023-1032 (2008)
  2. Human platelet 12-lipoxygenase, new findings about its activity, membrane binding and low-resolution structure. Aleem AM, Jankun J, Dignam JD, Walther M, Kühn H, Svergun DI, Skrzypczak-Jankun E. J Mol Biol 376 193-209 (2008)
  3. Structure of a calcium-dependent 11R-lipoxygenase suggests a mechanism for Ca2+ regulation. Eek P, Järving R, Järving I, Gilbert NC, Newcomer ME, Samel N. J Biol Chem 287 22377-22386 (2012)
  4. Connecting lipoxygenase function to structure by electron paramagnetic resonance. Gaffney BJ. Acc Chem Res 47 3588-3595 (2014)
  5. Fluctuations of an exposed π-helix involved in lipoxygenase substrate recognition. Bradshaw MD, Gaffney BJ. Biochemistry 53 5102-5110 (2014)
  6. Room-temperature crystallography using a microfluidic protein crystal array device and its application to protein-ligand complex structure analysis. Maeki M, Ito S, Takeda R, Ueno G, Ishida A, Tani H, Yamamoto M, Tokeshi M. Chem Sci 11 9072-9087 (2020)
  7. Hits-to-Lead Optimization of the Natural Compound 2,4,6-Trihydroxy-3-geranyl-acetophenone (tHGA) as a Potent LOX Inhibitor: Synthesis, Structure-Activity Relationship (SAR) Study, and Computational Assignment. Ng CH, Rullah K, Abas F, Lam KW, Ismail IS, Jamaludin F, Shaari K. Molecules 23 E2509 (2018)
  8. Comparison of side-chain dispersion in protein structures determined by cryo-EM and X-ray crystallography. Ravikumar A, Gopnarayan MN, Subramaniam S, Srinivasan N. IUCrJ 9 98-103 (2022)
  9. Computational Analysis of LOX1 Inhibition Identifies Descriptors Responsible for Binding Selectivity. Gousiadou C, Kouskoumvekaki I. ACS Omega 3 2261-2272 (2018)


Related citations provided by authors (2)

  1. Structure of soybean lipoxygenase L3 and a comparison with its L1 isoenzyme. Skrzypczak-Jankun E, Amzel LM, Kroa B, Funk MO Proteins 29 15-31 (1997)
  2. Flash-freezing causes a stress induced modulation in a crystal structure of soybean lipoxygenase L3. Skrzypczak-Jankun E, Bianchet M, Amzel LM, Funk MO Acta Crystallogr. D Biol. Crystallogr. 52 959-965 (1996)

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