Cataract is the leading cause of blindness in the world. It results from aggregation of eye lens proteins into high-molecular-weight complexes, causing light scattering and lens opacity. Copper and zinc concentrations in cataractous lens are increased significantly relative to a healthy lens, and a variety of experimental and epidemiological studies implicate metals as potential etiological agents for cataract. The natively monomeric, β-sheet rich human γD (HγD) crystallin is one of the more abundant proteins in the core of the lens. It is also one of the most thermodynamically stable proteins in the human body. Surprisingly, we found that both Cu(II) and Zn(II) ions induced rapid, nonamyloid aggregation of HγD, forming high-molecular-weight light-scattering aggregates. Unlike Zn(II), Cu(II) also substantially decreased the thermal stability of HγD and promoted the formation of disulfide-bridged dimers, suggesting distinct aggregation mechanisms. In both cases, however, metal-induced aggregation depended strongly on temperature and was suppressed by the human lens chaperone αB-crystallin (HαB), implicating partially folded intermediates in the aggregation process. Consistently, distinct site-specific interactions of Cu(II) and Zn(II) ions with the protein and conformational changes in specific hinge regions were identified by nuclear magnetic resonance. This study provides insights into the mechanisms of metal-induced aggregation of one of the more stable proteins in the human body, and it reveals a novel and unexplored bioinorganic facet of cataract disease.
Type 2 diabetes (T2D) is one of the most common chronic diseases, affecting over 300 million people worldwide. One of the hallmarks of T2D is the presence of amyloid deposits of human islet amyloid polypeptide (IAPP) in the islets of Langerhans of pancreatic β-cells. Recent reports indicate that Cu(II) can inhibit the aggregation of human IAPP, although the mechanism for this inhibitory effect is not clear. In this study, different spectroscopic techniques and model fragments of IAPP were employed to shed light on the structural basis for the interaction of Cu(II) with human IAPP. Our results show that Cu(II) anchors to His18 and the subsequent amide groups toward the C-terminal, forming a complex with an equatorial coordination mode 3N1O at physiological pH. Cu(II) binding to truncated IAPP at the His18 region is the key event for its inhibitory effect in amyloid aggregation. Electron paramagnetic resonance studies indicate that the monomeric Cu(II)-IAPP(15-22) complex differs significantly from Cu(II) bound to mature IAPP(15-22) fibers, suggesting that copper binding to monomeric IAPP(15-22) competes with the conformation changes needed to form β-sheet structures, thus delaying fibril formation. A general mechanism is proposed for the inhibitory effect of copper and other imidazole-binding metal ions in IAPP amyloid formation, providing further insights into the bioinorganic chemistry of T2D.
The prion protein (PrP(C)) is implicated in the spongiform encephalopathies in mammals, and it is known to bind Cu(II) at the N-terminal region. The region around His111 has been proposed to be key for the conversion of normal PrP(C) to its infectious isoform PrP(Sc). The principal aim of this study is to understand the role of protons and methionine residues 109 and 112 in the coordination of Cu(II) to the peptide fragment 106-115 of human PrP, using different spectroscopic techniques (UV-vis absorption, circular dichroism, and electron paramagnetic resonance) in combination with detailed electronic structure calculations. Our study has identified a proton equilibrium with a pK(a) of 7.5 associated with the Cu(II)-PrP(106-115) complex, which is ascribed to the deprotonation of the Met109 amide group, and it converts the site from a 3NO to a 4N equatorial coordination mode. These findings have important implications as they imply that the coordination environment of this Cu binding site at physiological pH is a mixture of two species. This study also establishes that Met109 and Met112 do not participate as equatorial ligands for Cu, and that Met112 is not an essential ligand, while Met109 plays a more important role as a weak axial ligand, particularly for the 3NO coordination mode. A role for Met109 as a highly conserved residue that is important to regulate the protonation state and redox activity of this Cu binding site, which in turn would be important for the aggregation and amyloidogenic properties of the protein, is proposed.
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