Stapled Peptides for Intracellular Drug Targets

Proteins that engage in intracellular interactions with other proteins are widely considered among the most biologically appealing yet chemically intractable targets for drug discovery. The critical interaction surfaces of these proteins typically lack the deep hydrophobic involutions that enable po...

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Veröffentlicht in:	Methods in Enzymology 2012, Vol.503, p.3-33
Hauptverfasser:	Verdine, Gregory L., Hilinski, Gerard J.
Format:	Artikel
Sprache:	eng
Schlagworte:	All-hydrocarbon staples Alpha-helix stabilization Amino Acid Sequence Animals Cell Membrane Permeability Cell permeability Cell-Penetrating Peptides - chemical synthesis Cell-Penetrating Peptides - chemistry Cell-Penetrating Peptides - therapeutic use Drug Delivery Systems - methods Flow Cytometry Half-Life Humans Hydrocarbons - chemistry Miniproteins Molecular Sequence Data Protein Folding Protein Interaction Domains and Motifs Protein Stability Protein Structure, Secondary Protein Transport Proteolysis Stapled peptides Structure-Activity Relationship Substrate Specificity
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description	Proteins that engage in intracellular interactions with other proteins are widely considered among the most biologically appealing yet chemically intractable targets for drug discovery. The critical interaction surfaces of these proteins typically lack the deep hydrophobic involutions that enable potent, selective targeting by small organic molecules, and their localization within the cell puts them beyond the reach of protein therapeutics. Considerable interest has therefore arisen in next-generation targeting molecules that combine the broad target recognition capabilities of protein therapeutics with the robust cell-penetrating ability of small molecules. One type that has shown promise in early-stage studies is hydrocarbon-stapled α-helical peptides, a novel class of synthetic miniproteins locked into their bioactive α-helical fold through the site-specific introduction of a chemical brace, an all-hydrocarbon staple. Stapling can greatly improve the pharmacologic performance of peptides, increasing their target affinity, proteolytic resistance, and serum half-life while conferring on them high levels of cell penetration through endocytic vesicle trafficking. Here, we discuss considerations crucial to the successful design and evaluation of potent stapled peptide interactions, our intention being to facilitate the broad application of this technology to intractable targets of both basic biologic interest and potential therapeutic value.
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subjects	All-hydrocarbon staples Alpha-helix stabilization Amino Acid Sequence Animals Cell Membrane Permeability Cell permeability Cell-Penetrating Peptides - chemical synthesis Cell-Penetrating Peptides - chemistry Cell-Penetrating Peptides - therapeutic use Drug Delivery Systems - methods Flow Cytometry Half-Life Humans Hydrocarbons - chemistry Miniproteins Molecular Sequence Data Protein Folding Protein Interaction Domains and Motifs Protein Stability Protein Structure, Secondary Protein Transport Proteolysis Stapled peptides Structure-Activity Relationship Substrate Specificity
title	Stapled Peptides for Intracellular Drug Targets
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