Anatol Koutychenko scite author profile

Anatol Koutychenko

3Publications

24Citation Statements Received

63Citation Statements Given

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Biotechnology Research Institute

Publications

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Rational design and selection of bivalent peptide ligands of thrombin incorporating P4-P1 tetrapeptide sequences: from good substrates to potent inhibitors

Vinogradova

Koutychenko

et al. 2004

Protein Engineering Design and Selection

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The tetrapeptide Phe-Asn-Pro-Arg is a structurally optimized sequence for binding to the active site of thrombin. By conjugating this tetrapeptide or some variants to a C-terminal fragment of hirudin, we were able to generate a series of new bivalent inhibitors of thrombin containing only genetically encodable natural amino acids. We found that synergistic binding to both the active site and an exosite of thrombin can be enhanced through substitutions of amino acid residues at the P3 and P3' sites of the active-site directed sequence, Phe(P4)-Xaa(P3)-Pro(P2)-Arg(P1)-Pro(P1')-Gln(P2')-Yaa(P3'). Complementary to rational design, a phage library was constructed to explore further the residue requirements at the P4, P3 and P3' sites for bivalent and optimized two-site binding. Very significantly, panning of the phage library has led to thrombin-inhibitory peptides possessing strong anti-clotting activities in the low nanomolar range and yet interfering only partially the catalytic active site of thrombin. Modes of action of the newly discovered bivalent inhibitors are rationalized in light of the allosteric properties of thrombin, especially the interplay between the proteolytic action and regulatory binding occurring at thrombin surfaces remote from the catalytic active site.

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Stability of protein‐bound conformations of bioactive peptides: The folded conformation of an epidermal growth factor‐like thrombomodulin fragment is similar to that recognized by thrombin

Song

Koutychenko

et al. 2002

Biopolymers

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The relationship between the free and bound conformations of bioactive peptides is explored using the epidermal growth factor (EGF)-like thrombomodulin fragment hTM409-426 as a model system. The hTM409-426 peptide has a sequence of C(409)PEGYILDDGFIC(421)TDIDE (with a disulfide bond between Cys409 and Cys421) and is a selective inhibitor of thrombin. Upon binding to thrombin, hTM409-426 adopts a well-defined conformation-namely, a beta-turn followed by an antiparallel beta-sheet, similar to those found in all other EGF-like protein repeats (Hrabal et al., Protein Science, 1996, Vol. 5, 195-203). Here we demonstrate that, at pH 6.8 and at 25 degrees C, the hTM409-426 peptide in the free state is very flexible, but still populates a type II beta-turn over residues Pro410-Glu411-Gly412-Tyr413 and the clustering of some hydrophobic side chains, both of which are present in the thrombin-bound conformation. At a lower temperature of 5 degrees C, significant conformational shifts of the C alpha H proton resonances and extensive medium- and long-range NOEs are observed, indicating the presence of folded conformations with unique backbone-backbone and side-chain interactions. A comparison of the NOE patterns in the free state with transferred NOEs shows that the free-state folded and the thrombin-bound conformations of the hTM409-426 peptide are very similar, particularly over residues Pro410-Ile424. The folded conformation of hTM409-426 appears to be stabilized by two hydrophobic clusters, one formed by the side chains of residues Pro410, Tyr413, Leu415, and Phe419 and the Cys409-Cys421 disulfide bond, the second involving residues Ile414 and Ile424. These results indicate that the overall topology of the thrombin-bound conformation of the hTM409-426 peptide is prefolded in the free state and the primary sequence (including the disulfide bond) may be selective for an ensemble of conformations similar to that recognized by thrombin.

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Dissecting Functional Interactions in Coagulation Protein Complexes by Use of NMR Spectroscopy

Talkatchev

Koutychenko²,

Ni³

2002

curr protein pept sci

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The blood coagulation cascade can be considered as a system of well-orchestrated protein activation reactions involving and leading to the formation of large macromolecular assemblies. NMR investigations performed during the last six years have focused on the structural, motional and binding properties of some protein domains and interfaces critical for the formation of these protein complexes, outlining sophisticated intermolecular adaptations. The studied protein domains are either single molecules or covalently-linked heterodimers of the epidermal growth factor (EGF) homology domains, calcium-binding EGF domains and gamma-carboxyglutamic(Gla)-containing domains responsible for calcium-dependent binding to cell membranes. The characterized binding interfaces have included those between thrombin and fibrinogen, between thrombin and thrombomodulin, between factor VIIIa and the cell membrane, between tissue factor and factor VIIa, and most recently between factor Va and prothrombin. The obtained results indicate that the regulation of blood coagulation by protein and low molecular weight cofactors may involve a significant degree of protein folding transitions with changes in molecular and conformational motions coupled to enzymatic activities. This new level of complexity of the molecular processes controlling coagulation may lead to novel strategies for the development of more effective therapeutic anticoagulants.

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