拟肽
化学
组合化学
药物发现
扁桃体
计算生物学
蛋白质-蛋白质相互作用
肽
区域选择性
生物化学
生物
催化作用
作者
Anna Russo,Carmela Aiello,Paolo Grieco,Daniela Marasco
标识
DOI:10.2174/0929867323666160112122540
摘要
The development of synthetic macrocycles represents a powerful approach toward the identification of new protein binders or inhibitors of Protein-Protein Interactions (PPI) which are known to play key biological roles in cancer signaling as well as in the regulation of cell division cycle. Structural investigations led to identify “hot loops” sharing common motifs that are mainly involved in PPIs. Most PPIs occur through large and flat surfaces; currently these protein complexes are defined as “undruggable” by conventional drug-discovery approaches, since the identification of small molecules to inhibit these targets is often unreachable. Typically macrocycles are 500-2000 Da in size, having 12-membered, or more, ring architecture: they do not obey the Lipinski’s rule but, for them nature offers many examples as therapeutic agents such as erythromycin (antibiotic), cyclosporin (immunosuppressant) and somatostatin (hormone). Peptide-based macrocycles offer the advantages of directly mimicking secondary structures involved in PPIs and their pharmacological application is related to the potential improvement of lead peptides in terms of potency, selectivity, stability and cell permeation. The promising relevance of cyclopeptides prompted to develop new synthetic methods for cyclization: often biotechnological approaches as well as regioselective reactions have been employed to cyclize peptides rapidly and nearly quantitatively. Moreover, different synthetic strategies in peptidomimetics’ macrocyclization are actually available based on surrogate peptide bonds or NCL (Native Chemical Ligation) methods. In this review we focus on the most common methods for the preparation of cyclopeptides and interesting applications of the last decade. Keywords: Protein-Protein Interactions, Macrocycles, Cyclopeptides.
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