Delineating the impact of N21D mutation on the conformational preferences and structural transitions in human islet amyloid polypeptide

Abstract

The amyloid deposits of human islet amyloid polypeptide (hIAPP) in the pancreatic β-cells are linked to a chronic metabolic disease known as type 2 diabetes (T2D). Recent studies reported that N21D mutation in hIAPP inhibited the formation of fibrillar aggregates, however, the underlying molecular mechanism of fibril inhibition in the N21D mutant remains largely unclear. Thus, molecular dynamics (MD) simulations have been employed to illuminate the effect of N21D mutation on the conformational dynamics and structural transformations in hIAPP at the atomistic level. Notably, the structural stability of WT-hIAPP (wild type-hIAPP) was enhanced upon N21D mutation. Interestingly, the sampling of helical conformation in hIAPP was significantly increased from 12.60 to 19.80% with a concomitant decrease in β-sheet from 7.40 to 1.20% upon N21D mutation that corroborates with the circular dichroism (CD). The dihedral principal component analysis (dPCA) depicted a notable reduction in the conformational phase space of [N21D]hIAPP as compared to WT-hIAPP, which highlights the prevention of conformational transitions and enhanced structural stability. Remarkably, a complete loss in the β-sheet content was noted in the conformations extracted from the free energy landscape of [N21D]hIAPP as compared to 24–25% sampling of β-sheets in minimum energy conformations of WT-hIAPP consistent with the transmission electron microscopy (TEM) and thioflavin T (ThT) fluorescence assay. The present study provided key insights into the N21D mutation-induced conformational changes in hIAPP and highlighted that Asn21 plays a key role in hIAPP aggregation. The insights from this work will be beneficial in the design of drug candidates by selectively targeting Asn21 of hIAPP which could interfere with its aggregation and associated cytotoxicity.