Dirk Wildemann scite author profile

Human Pin1 is a key regulator of cell-cycle progression and plays growth-promoting roles in human cancers. High-affinity inhibitors of Pin1 may provide a unique opportunity for disrupting oncogenic pathways. Here we report two high-resolution X-ray crystal structures of human Pin1 bound to non-natural peptide inhibitors. The structures of the bound high-affinity peptides identify a type-I beta-turn conformation for Pin1 prolyl peptide isomerase domain-peptide binding and an extensive molecular interface for high-affinity recognition. Moreover, these structures suggest chemical elements that may further improve the affinity and pharmacological properties of future peptide-based Pin inhibitors. Finally, an intramolecular hydrogen bond observed in both peptide complexes mimics the cyclic conformation of FK506 and rapamycin. Both FK506 and rapamycin are clinically important inhibitors of other peptidyl-prolyl cis-trans isomerases. This comparative discovery suggests that a cyclic peptide polyketide bridge, like that found in FK506 and rapamycin or a similar linkage, may significantly improve the binding affinity of structure-based Pin1 inhibitors.

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Mapping backbone and side-chain interactions in the transition state of a coupled protein folding and binding reaction

Bachmann

Wildemann

Praetorius

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

119

147

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Understanding the mechanism of protein folding requires a detailed knowledge of the structural properties of the barriers separating unfolded from native conformations. The S-peptide from ribonuclease S forms its α-helical structure only upon binding to the folded S-protein. We characterized the transition state for this binding-induced folding reaction at high resolution by determining the effect of site-specific backbone thioxylation and side-chain modifications on the kinetics and thermodynamics of the reaction, which allows us to monitor formation of backbone hydrogen bonds and side-chain interactions in the transition state. The experiments reveal that α-helical structure in the S-peptide is absent in the transition state of binding. Recognition between the unfolded S-peptide and the S-protein is mediated by loosely packed hydrophobic side-chain interactions in two well defined regions on the S-peptide. Close packing and helix formation occurs rapidly after binding. Introducing hydrophobic residues at positions outside the recognition region can drastically slow down association.phi-value analysis | protein-protein interaction | encounter complex formation | thioxo peptide bond C onformational changes in proteins play an important role in many biological processes. A detailed understanding of the mechanism of conformational transitions requires knowledge of the structural and dynamic properties of the initial and final states as well as the characterization of the transition barrier separating them. Site-directed mutagenesis proved a powerful tool to determine the properties of transition states for reactions involving proteins. Comparing the effect of amino acid replacements on kinetics and thermodynamics of a reaction identifies the interactions that are important for the rate-limiting step of a process. This method has been successfully applied to characterize transition states for protein folding (1, 2), for proteinprotein interactions (3-5) and for conformational changes in folded proteins (6). Protein folding transition states were shown to have native-like topology in the whole protein or in major parts of the structure (7-9) and it is commonly assumed that this includes the presence of native-like secondary structure (10, 11). Because site-directed mutagenesis can only modify amino acid side chains, it is still unclear at which stage of a folding reaction backbone hydrogen bonds in secondary structure elements are formed. Several approaches have been applied to test for secondary structure in protein folding transition states. Replacing amino acids by glycyl and prolyl residues leads to changes in backbone conformation, which was used to probe α-helix formation (12), but these replacements introduce additional effects due to altered side-chain interactions. Introducing ester bonds into the polypeptide backbone (13) also has multiple effects because it leads to the loss of a backbone hydrogen bonding donor and strongly increases conformational flexibility of the polypeptide backbone. Deuteration of a...

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Nanomolar Inhibitors of the Peptidyl Prolyl Cis/Trans Isomerase Pin1 from Combinatorial Peptide Libraries

et al. 2006

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The peptidyl prolyl cis/trans isomerase Pin1 has been implicated in the development of cancer, Alzheimer's disease and asthma, but highly specific and potent Pin1 inhibitors remain to be identified. Here, by screening a combinatorial peptide library, we identified a series of nanomolar peptidic inhibitors. Nonproteinogenic amino acids, incorporated into 5-mer to 8-mer oligopeptides containing a d-phosphothreonine as a central template, yielded selective inhibitors that blocked cell cycle progression in HeLa cells in a dose-dependent manner.

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Dirk Wildemann

Structural Basis for High-Affinity Peptide Inhibition of Human Pin1

Mapping backbone and side-chain interactions in the transition state of a coupled protein folding and binding reaction

Nanomolar Inhibitors of the Peptidyl Prolyl Cis/Trans Isomerase Pin1 from Combinatorial Peptide Libraries

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