ABSTRACT
Dehydroascorbate is a by-product of copper-catalysed azide-alkyne click (CuAAC) reactions and also forms advanced glycation end products (AGEs) in tissues undergoing oxidative stress. Here we isolate and characterize an arginine-dehydroascorbate adduct formed during CuAAC reactions, investigate strategies for preventing its formation, and propose its biological relevance as an AGE.
Subject(s)
Alkynes/chemistry , Arginine/chemistry , Azides/chemistry , Copper/chemistry , Dehydroascorbic Acid/chemical synthesis , Glycation End Products, Advanced/chemical synthesis , Catalysis , Click Chemistry , Dehydroascorbic Acid/chemistry , Glycation End Products, Advanced/chemistry , Molecular StructureABSTRACT
The design of inhibitors of protein-protein interactions mediating amyloid self-assembly is a major challenge mainly due to the dynamic nature of the involved structures and interfaces. Interactions of amyloidogenic polypeptides with other proteins are important modulators of self-assembly. Here we present a hot-segment-linking approach to design a series of mimics of the IAPP cross-amyloid interaction surface with Aß (ISMs) as nanomolar inhibitors of amyloidogenesis and cytotoxicity of Aß, IAPP, or both polypeptides. The nature of the linker determines ISM structure and inhibitory function including both potency and target selectivity. Importantly, ISMs effectively suppress both self- and cross-seeded IAPP self-assembly. Our results provide a novel class of highly potent peptide leads for targeting protein aggregation in Alzheimer's disease, type 2 diabetes, or both diseases and a chemical approach to inhibit amyloid self-assembly and pathogenic interactions of other proteins as well.