Carolina Sánchez-López scite author profile

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.

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Copper Coordination Features of Human Islet Amyloid Polypeptide: The Type 2 Diabetes Peptide

Sánchez-López

Cortés-Mejía

Miotto

et al. 2016

Inorg. Chem.

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Human islet amyloid polypeptide (hIAPP) is the major component of amyloid deposits found in pancreatic β-cells of patients with type 2 diabetes (T2D). Copper ions have an inhibitory effect on the amyloid aggregation of hIAPP, and they may play a role in the etiology of T2D. However, deeper knowledge of the structural details of the copper− hIAPP interaction is required to understand the molecular mechanisms involved. Here, we performed a spectroscopic study of Cu(II) binding to hIAPP and several variants, using electron paramagnetic resonance (EPR), nuclear magnetic resonance (NMR), electronic absorption, and circular dichroism (CD) in the UV−vis region in combination with Born−Oppenheimer molecular dynamics (BOMD) and density functional theory geometry optimizations. We find that Cu(II) binds to the imidazole N1 of His18, the deprotonated amides of Ser19 and Ser20, and an oxygen-based ligand provided by Ser20, either via its hydroxyl group or its backbone carbonyl, while Asn22 might also play a role as an axial ligand. Ser20 plays a crucial role in stabilizing Cu(II) coordination toward the Cterminal, providing a potential link between the S20G mutation associated with early onset of T2D, its impact in Cu binding properties, and hIAPP amyloid aggregation. Our study defines the nature of the coordination environment in the Cu(II)−hIAPP complex, revealing that the amino acid residues involved in metal ion binding are also key residues for the formation of β-sheet structures and amyloid fibrils. Cu(II) binding to hIAPP may lead to the coexistence of more than one coordination mode, which in turn could favor different sets of Cu-induced conformational ensembles. Cu-induced hIAPP conformers would display a higher energetic barrier to form amyloid fibrils, hence explaining the inhibitory effect of Cu ions in hIAPP aggregation. Overall, this study provides further structural insights into the bioinorganic chemistry of T2D.

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Structural Determinants of the Prion Protein N-Terminus and Its Adducts with Copper Ions

Sánchez-López

Rossetti

Quintanar

et al. 2018

IJMS

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The N-terminus of the prion protein is a large intrinsically disordered region encompassing approximately 125 amino acids. In this paper, we review its structural and functional properties, with a particular emphasis on its binding to copper ions. The latter is exploited by the region’s conformational flexibility to yield a variety of biological functions. Disease-linked mutations and proteolytic processing of the protein can impact its copper-binding properties, with important structural and functional implications, both in health and disease progression.

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Methionine 109 plays a key role in Cu(II) binding to His111 in the 92–115 fragment of the human prion protein

Sánchez-López

Rivillas‐Acevedo

Cruz-Vásquez

et al. 2018

Inorganica Chimica Acta

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Neuroprotective alpha-cleavage of the human prion protein significantly impacts Cu(ii) coordination at its His111 site

2018

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The cellular prion protein (PrPC) is a copper binding protein that undergoes post-translational modifications, such as endoproteolytic alpha cleavage, which occurs in the vicinity of the His111 Cu binding site. Alpha cleavage processing of PrPC is considered to be neuroprotective since the cleavage site is located in a region that is key to the conversion of PrPC into the infectious scrapie isoform (PrPSc), yielding a membrane bound C1 fragment of PrPC that still contains His111. In this work, we use hPrP(111-115) fragment as a model peptide to evaluate the impact of alpha cleavage processing of PrPC in its ability to coordinate Cu(ii) ions at His111. By using different spectroscopic techniques such as electronic absorption, circular dichroism, nuclear magnetic resonance, and electron paramagnetic resonance, this study demonstrates that Cu(ii) binding to the cleaved His111 site is highly dependent on Cu and proton concentrations. The imidazole group of His111 and its free NH2 terminus emerge as the main anchoring sites for Cu(ii) coordination, yielding very different complexes from those characterized for the intact His111 site in the full protein. Different Cu(ii) coordination modes that could form with the alpha cleaved PrPC under physiological conditions are identified and characterized. Overall, this study contributes to understand how alpha cleavage processing of PrPC impacts its Cu(ii) binding properties at His111. While the functional implications of Cu binding to the cleaved PrPC remain to be discovered, proteolytic processing of PrPC and its Cu binding features appear to be molecular events that might be strongly linked to its cellular function.

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