3arp Citations

Potent family-18 chitinase inhibitors: x-ray structures, affinities, and binding mechanisms.

Pantoom S, Vetter IR, Prinz H, Suginta W
J Biol Chem 286 24312-23 (2011)
Related entries: 3aro, 3arq, 3arr, 3ars, 3art, 3aru, 3arv, 3arw, 3arx, 3ary, 3arz, 3as0, 3as1, 3as2, 3as3, 3b8s, 3b9a, 3b9d, 3b9e

Cited: 14 times
EuropePMC logo PMID: 21531720

Abstract

Six novel inhibitors of Vibrio harveyi chitinase A (VhChiA), a family-18 chitinase homolog, were identified by in vitro screening of a library of pharmacologically active compounds. Unlike the previously identified inhibitors that mimicked the reaction intermediates, crystallographic evidence from 14 VhChiA-inhibitor complexes showed that all of the inhibitor molecules occupied the outer part of the substrate-binding cleft at two hydrophobic areas. The interactions at the aglycone location are well defined and tightly associated with Trp-397 and Trp-275, whereas the interactions at the glycone location are patchy, indicating lower affinity and a loose interaction with two consensus residues, Trp-168 and Val-205. When Trp-275 was substituted with glycine (W275G), the binding affinity toward all of the inhibitors dramatically decreased, and in most structures two inhibitor molecules were found to stack against Trp-397 at the aglycone site. Such results indicate that hydrophobic interactions are important for binding of the newly identified inhibitors by the chitinase. X-ray data and isothermal microcalorimetry showed that the inhibitors occupied the active site of VhChiA in three different binding modes, including single-site binding, independent two-site binding, and sequential two-site binding. The inhibitory effect of dequalinium in the low nanomolar range makes this compound an extremely attractive lead compound for plausible development of therapeutics against human diseases involving chitinase-mediated pathologies.

Articles - 3arp mentioned but not cited (7)

  1. Deep Generative Models for 3D Linker Design. Imrie F, Bradley AR, van der Schaar M, Deane CM. J Chem Inf Model 60 1983-1995 (2020)
  2. SyntaLinker: automatic fragment linking with deep conditional transformer neural networks. Yang Y, Zheng S, Su S, Zhao C, Xu J, Chen H. Chem Sci 11 8312-8322 (2020)
  3. Potent family-18 chitinase inhibitors: x-ray structures, affinities, and binding mechanisms. Pantoom S, Vetter IR, Prinz H, Suginta W. J Biol Chem 286 24312-24323 (2011)
  4. Machine-Learning- and Knowledge-Based Scoring Functions Incorporating Ligand and Protein Fingerprints. Fujimoto KJ, Minami S, Yanai T. ACS Omega 7 19030-19039 (2022)
  5. Diversity-guided Lamarckian random drift particle swarm optimization for flexible ligand docking. Li C, Sun J, Palade V. BMC Bioinformatics 21 286 (2020)
  6. Divide-and-conquer strategy for large-scale Eulerian solvent excluded surface. Zhao R, Wang M, Tong Y, Wei GW. Commun Inf Syst 18 299-329 (2018)
  7. Assessing How Residual Errors of Scoring Functions Correlate to Ligand Structural Features. Shulga DA, Shaimardanov AR, Ivanov NN, Palyulin VA. Int J Mol Sci 23 15018 (2022)


Articles citing this publication (7)

  1. Chitinases are negative regulators of Francisella novicida biofilms. Chung MC, Dean S, Marakasova ES, Nwabueze AO, van Hoek ML. PLoS One 9 e93119 (2014)
  2. Structural Insight Into Chitin Degradation and Thermostability of a Novel Endochitinase From the Glycoside Hydrolase Family 18. Wang YJ, Jiang WX, Zhang YS, Cao HY, Zhang Y, Chen XL, Li CY, Wang P, Zhang YZ, Song XY, Li PY. Front Microbiol 10 2457 (2019)
  3. Multiple roles of Asp313 in the refined catalytic cycle of chitin degradation by Vibrio harveyi chitinase A. Suginta W, Sritho N. Biosci Biotechnol Biochem 76 2275-2281 (2012)
  4. Identification and Characterization of Three Chitinases with Potential in Direct Conversion of Crystalline Chitin into N,N'-diacetylchitobiose. Ren XB, Dang YR, Liu SS, Huang KX, Qin QL, Chen XL, Zhang YZ, Wang YJ, Li PY. Mar Drugs 20 165 (2022)
  5. Structural dissection reveals a general mechanistic principle for group II chitinase (ChtII) inhibition. Chen W, Zhou Y, Yang Q. J Biol Chem 294 9358-9364 (2019)
  6. Simplification traps. Prinz H. J Chem Biol 5 1-4 (2012)
  7. Discovery of Kasugamycin as a Potent Inhibitor of Glycoside Hydrolase Family 18 Chitinases. Qi H, Jiang X, Ding Y, Liu T, Yang Q. Front Mol Biosci 8 640356 (2021)


Related citations provided by authors (1)

  1. Crystal structures of Vibrio harveyi chitinase A complexed with chitooligosaccharides: implications for the catalytic mechanism.. Songsiriritthigul C, Pantoom S, Aguda AH, Robinson RC, Suginta W J Struct Biol 162 491-9 (2008)

Quick links