Abstract
Membrane environment often has an important effect on the structure, and therefore also on the coordination mode of biologically relevant metal ions. This is also true in the case of Cu(II) coordination to amylin analogues—rat amylin, amylin1–19, pramlintide and Ac-pramlintide, which offer N-terminal amine groups and/or histidine imidazoles as copper(II) anchoring sites. Complex stabilities are comparable, with the exception of the very stable Cu(II)–amylin1–19, which proves that the presence of the amylin C-terminus lowers its affinity for copper(II); although not directly involved, its appropriate arrangement sterically prevents early metal binding. Most interestingly, in membrane-mimicking solution, the Cu(II) affinities of amylin analogues are lower than the ones in water, probably due to the crowding effect of the membrane solution and the fact that amide coordination occurs at higher pH, which happens most likely because the α-helical structure, imposed by the membrane-mimicking solvent, prevents the amides from binding at lower pH, requiring a local unwinding of the α-helix.
Highlights
Membrane environment often has an important effect on the structure, and on the coordination mode of biologically relevant metal ions
Protein misfolding and formation of amyloidogenic aggregates are features of disorders belonging to the group of protein misfolding diseases (PMDs) including Type 2 Diabetes Mellitus (T2DM)
Because of the crucial impact of membrane environment on the structure and metal binding ability of amylin, in this work, we present the coordination chemistry of copper(II) complexes with non-amyloidogenic rat amylin, the non-aggregating fragment of amylin 1–19, pramlintide and Ac-pramlintide in membrane mimicking environment (SDS, sodium dodecyl sulfate)
Summary
Membrane environment often has an important effect on the structure, and on the coordination mode of biologically relevant metal ions. As shown in a recent study by Khemtemourian et al, conducted in the presence of a lipid membrane using amylin analogues in which His[18] was replaced by other amino acid residues, the presence of zinc(II) ions does not affect the fibrillation process of a mylin[26]. It has been confirmed in Brender’s NMR experiment which showed the N-terminus is involved in interactions with the membrane and becomes inaccessible to zinc(II)[27]. This contradicts earlier reports that zinc(II) ions, depending on their concentration, may have an inhibitory[28] or stimulatory effect on the peptide folding process[29,30]
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