Your search keyword '"Engel, Maarten F. M."' showing total 2 results

1. Membrane damage by human islet amyloid polypeptide through fibril growth at the membrane.

Author

Engel, Maarten F. M., Khemtémourian, Lucie, Kleijer, Cécile C., Meeldijk, Hans J. D., Jacobs, Jet, Verkleij, Arie J., de Kruijff, Ben, Killian, Antoinette J., and Höppener, Jo W. M.

Subjects

*AMYLOID beta-protein, *APOPTOSIS, *DIABETES, *PANCREATIC secretions, *ELECTRON microscopy

Abstract

Fibrillar protein deposits (amyloid) in the pancreatic islets of Langerhans are thought to be involved in death of the insulin- producing islet β cells in type 2 diabetes mellitus. It has been suggested that the mechanism of this β cell death involves membrane disruption by human islet amyloid polypeptide (hIAPP), the major constituent of islet amyloid. However, the molecular mechanism of hIAPP-induced membrane disruption is not known. Here, we propose a hypothesis that growth of hIAPP fibrils at the membrane causes membrane damage. We studied the kinetics of hIAPP-induced membrane damage in relation to hIAPP fibril growth and found that the kinetic profile of hIAPP-induced membrane damage is characterized by a lag phase and a sigmoidal transition, which matches the kinetic profile of hIAPP fibril growth. The observation that seeding accelerates membrane damage supports the hypothesis. In addition, variables that are well known to affect hIAPP fibril formation, i.e., the presence of a fibril formation inhibitor, hIAPP concentration, and lipid composition, were found to have the same effect on hIAPP-induced membrane damage. Furthermore, electron microscopy analysis showed that hIAPP fibrils line the surface of distorted phospholipid vesicles, in agreement with the notion that hIAPP fibril growth at the membrane and membrane damage are physically connected. Together, these observations point toward a mechanism in which growth of hIAPP fibrils, rather than a particular hIAPP species, is responsible for the observed membrane damage. This hypothesis provides an additional mechanism next to the previously proposed role of oligomers as the main cytotoxic species of amyloidogenic proteins. [ABSTRACT FROM AUTHOR]

Published

2008

2. Conformation and orientation of a protein folding intermediate trapped by adsorption.

Author

Engel, Maarten F. M., Visser, antonie J. W. G., and van Mierlo, Carolo P. M.

Subjects

*PROTEINS, *BIOMOLECULES, *ORGANIC compounds, *ADSORPTION (Chemistry), *SEPARATION (Technology), *SPECTRUM analysis

Abstract

Although adsorption-induced conformational changes of proteins play an essential role during protein adsorption on interfaces, detailed information about these changes is lacking. To further the current understanding of protein adsorption, in this study, the orientation, conformation, and local stability of bovine α-lactalbumin (B LA) adsorbed on polystyrene nanospheres is characterized at the residue level by hydrogen/deuterium exchange and 2D NMR spectroscopy. Most of the adsorbed BLA molecules have conformational properties similar to BLA molecules in the acid-induced molten globule state (A state). A folding intermediate of BLA is thus induced and trapped by adsorption of the protein on the hydrophobic interface. Several residues, clustered on one side of the adsorbed folding intermediate of BLA, have altered amide proton exchange protection factors compared to those of the A state of BLA. This side preferentially interacts with the interface and includes residues in helix C, the calcium binding site, and part of the β-domain. Local unfolding of this interacting part of the adsorbed protein seems to initiate the adsorption-induced unfolding of BLA. Adsorption-induced protein unfolding apparently resembles more the mechanical unfolding of a protein than the global unfolding of a protein as induced by denaturant, pH, or pressure. 2D macromolecular crowding prevented the minority of adsorbed BLA molecules, which arrived late at the interface, to unfold to the A state. Protein adsorption is a novel and challenging approach to probe features of the free energy landscapes accessible to unfolding proteins. [ABSTRACT FROM AUTHOR]

Published

2004