3u8o Citations

Rational design and characterization of D-Phe-Pro-D-Arg-derived direct thrombin inhibitors.

<div class='caption-title'>Structure of the peptide inhibitors characterized in complex with human α-thrombin.</div>
<div class='caption-title'>Inhibition of amidolytic activity of α-thrombin by peptide inhibitors.</div>
<div class='caption-title'>Prolongation of thrombin time by peptide inhibitors.</div>
Figueiredo AC, Clement CC, Zakia S, Gingold J, Philipp M, Pereira PJ
OpenAccess logo PLoS One 7 e34354 (2012)
Related entries: 3u69, 3u8r, 3u8t

Cited: 19 times
EuropePMC logo PMID: 22457833

Abstract

The tremendous social and economic impact of thrombotic disorders, together with the considerable risks associated to the currently available therapies, prompt for the development of more efficient and safer anticoagulants. Novel peptide-based thrombin inhibitors were identified using in silico structure-based design and further validated in vitro. The best candidate compounds contained both L- and D-amino acids, with the general sequence D-Phe(P3)-Pro(P2)-D-Arg(P1)-P1'-CONH₂. The P1' position was scanned with L- and D-isomers of natural or unnatural amino acids, covering the major chemical classes. The most potent non-covalent and proteolysis-resistant inhibitors contain small hydrophobic or polar amino acids (Gly, Ala, Ser, Cys, Thr) at the P1' position. The lead tetrapeptide, D-Phe-Pro-D-Arg-D-Thr-CONH₂, competitively inhibits α-thrombin's cleavage of the S2238 chromogenic substrate with a K(i) of 0.92 µM. In order to understand the molecular details of their inhibitory action, the three-dimensional structure of three peptides (with P1' L-isoleucine (fPrI), L-cysteine (fPrC) or D-threonine (fPrt)) in complex with human α-thrombin were determined by X-ray crystallography. All the inhibitors bind in a substrate-like orientation to the active site of the enzyme. The contacts established between the D-Arg residue in position P1 and thrombin are similar to those observed for the L-isomer in other substrates and inhibitors. However, fPrC and fPrt disrupt the active site His57-Ser195 hydrogen bond, while the combination of a P1 D-Arg and a bulkier P1' residue in fPrI induce an unfavorable geometry for the nucleophilic attack of the scissile bond by the catalytic serine. The experimental models explain the observed relative potency of the inhibitors, as well as their stability to proteolysis. Moreover, the newly identified direct thrombin inhibitors provide a novel pharmacophore platform for developing antithrombotic agents by exploring the conformational constrains imposed by the D-stereochemistry of the residues at positions P1 and P1'.

Articles - 3u8o mentioned but not cited (3)

  1. Rational design and characterization of D-Phe-Pro-D-Arg-derived direct thrombin inhibitors. Figueiredo AC, Clement CC, Zakia S, Gingold J, Philipp M, Pereira PJ. PLoS ONE 7 e34354 (2012)
  2. Ensemble refinement shows conformational flexibility in crystal structures of human complement factor D. Forneris F, Burnley BT, Gros P. Acta Crystallogr. D Biol. Crystallogr. 70 733-743 (2014)
  3. Predicting Displaceable Water Sites Using Mixed-Solvent Molecular Dynamics. Graham SE, Smith RD, Carlson HA. J Chem Inf Model 58 305-314 (2018)


Reviews citing this publication (1)

  1. Non-Canonical Amino Acids in Analyses of Protease Structure and Function. Goettig P, Koch NG, Budisa N. Int J Mol Sci 24 14035 (2023)

Articles citing this publication (15)

  1. Unique thrombin inhibition mechanism by anophelin, an anticoagulant from the malaria vector. Figueiredo AC, de Sanctis D, Gutiérrez-Gallego R, Cereija TB, Macedo-Ribeiro S, Fuentes-Prior P, Pereira PJ. Proc. Natl. Acad. Sci. U.S.A. 109 E3649-58 (2012)
  2. Nature versus design: the conformational propensities of D-amino acids and the importance of side chain chirality. Towse CL, Hopping G, Vulovic I, Daggett V. Protein Eng. Des. Sel. 27 447-455 (2014)
  3. Dissecting the contribution of thrombin exosite I in the recognition of thrombin binding aptamer. Pica A, Russo Krauss I, Merlino A, Nagatoishi S, Sugimoto N, Sica F. FEBS J. 280 6581-6588 (2013)
  4. Tyrosine sulfation modulates activity of tick-derived thrombin inhibitors. Thompson RE, Liu X, Ripoll-Rozada J, Alonso-García N, Parker BL, Pereira PJB, Payne RJ. Nat Chem 9 909-917 (2017)
  5. The tick-derived anticoagulant madanin is processed by thrombin and factor Xa. Figueiredo AC, de Sanctis D, Pereira PJ. PLoS ONE 8 e71866 (2013)
  6. Functional analyses yield detailed insight into the mechanism of thrombin inhibition by the antihemostatic salivary protein cE5 from Anopheles gambiae. Pirone L, Ripoll-Rozada J, Leone M, Ronca R, Lombardo F, Fiorentino G, Andersen JF, Pereira PJB, Arcà B, Pedone E. J. Biol. Chem. 292 12632-12642 (2017)
  7. Bufadienolides from Kalanchoe daigremontiana as thrombin inhibitors-In vitro and in silico study. Kolodziejczyk-Czepas J, Sieradzka M, Moniuszko-Szajwaj B, Pecio Ł, Ponczek MB, Nowak P, Stochmal A. Int. J. Biol. Macromol. 99 141-150 (2017)
  8. Dabigatran and Argatroban Diametrically Modulate Thrombin Exosite Function. Yeh CH, Stafford AR, Leslie BA, Fredenburgh JC, Weitz JI. PLoS ONE 11 e0157471 (2016)
  9. Combining flavin photocatalysis with parallel synthesis: a general platform to optimize peptides with non-proteinogenic amino acids. Immel JR, Chilamari M, Bloom S. Chem Sci 12 10083-10091 (2021)
  10. Identification of a substrate-like cleavage-resistant thrombin inhibitor from the saliva of the flea Xenopsylla cheopis. Lu S, Tirloni L, Oliveira MB, Bosio CF, Nardone GA, Zhang Y, Hinnebusch BJ, Ribeiro JM, Andersen JF. J Biol Chem 297 101322 (2021)
  11. Molecular dynamics simulations of aptamer-binding reveal generalized allostery in thrombin. Xiao J, Salsbury FR. J. Biomol. Struct. Dyn. 35 3354-3369 (2017)
  12. Selective albumin-binding surfaces modified with a thrombin-inhibiting peptide. Freitas SC, Maia S, Figueiredo AC, Gomes P, Pereira PJ, Barbosa MA, Martins MC. Acta Biomater 10 1227-1237 (2014)
  13. Development of new antiatherosclerotic and antithrombotic drugs utilizing F11 receptor (F11R/JAM-A) peptides. Babinska A, Clement CC, Swiatkowska M, Szymanski J, Shon A, Ehrlich YH, Kornecki E, Salifu MO. Biopolymers 102 322-334 (2014)
  14. Membrane disintegration by the antimicrobial peptide (P)GKY20: lipid segregation and domain formation. Oliva R, Del Vecchio P, Grimaldi A, Notomista E, Cafaro V, Pane K, Schuabb V, Winter R, Petraccone L. Phys Chem Chem Phys 21 3989-3998 (2019)
  15. The Dual Regulatory Role of Amino Acids Leu480 and Gln481 of Prothrombin. Wiencek JR, Hirbawi J, Yee VC, Kalafatis M. J. Biol. Chem. 291 1565-1581 (2016)


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