An attractive strategy to contrast the Alzheimer disease (AD) is represented by the development of ?-sheet breaker peptides (BSB). ?-sheet breakers constitute a class of compounds which have shown a good efficacy in preventing the A? fibrillogenesis; however, their mechanism of action has not been precisely understood. In this context, we have studied the structural basis underlying the inhibitory effect of A?(1-42) fibrillogenesis explicated by two promising trehalose-conjugated BSB peptides using an all-atom molecular dynamics (MD) approach. Our simulations suggest that the binding on the two protofibril ends occurs through different binding modes. In particular, binding on the odd edge (chain A) is guided by a well defined hydrophobic cleft, which is common to both ligands. Moreover, targeting chain A entails a significant structure destabilization leading to a partial loss of ? structure and is an energetically favoured process. A significant contribution of the trehalose moiety to the stability of the complexes emerged from our results. The energetically favoured hydrophobic cleft detected on chain A could represent a good starting point for the design of new molecules with improved anti-aggregating features. © 2013 The Royal Society of Chemistry.

Insights into the mechanism of interaction between trehalose-conjugated beta-sheet breaker peptides and A?(1-42) fibrils by molecular dynamics simulations

Autiero I;Langella E;Saviano M
2013

Abstract

An attractive strategy to contrast the Alzheimer disease (AD) is represented by the development of ?-sheet breaker peptides (BSB). ?-sheet breakers constitute a class of compounds which have shown a good efficacy in preventing the A? fibrillogenesis; however, their mechanism of action has not been precisely understood. In this context, we have studied the structural basis underlying the inhibitory effect of A?(1-42) fibrillogenesis explicated by two promising trehalose-conjugated BSB peptides using an all-atom molecular dynamics (MD) approach. Our simulations suggest that the binding on the two protofibril ends occurs through different binding modes. In particular, binding on the odd edge (chain A) is guided by a well defined hydrophobic cleft, which is common to both ligands. Moreover, targeting chain A entails a significant structure destabilization leading to a partial loss of ? structure and is an energetically favoured process. A significant contribution of the trehalose moiety to the stability of the complexes emerged from our results. The energetically favoured hydrophobic cleft detected on chain A could represent a good starting point for the design of new molecules with improved anti-aggregating features. © 2013 The Royal Society of Chemistry.
2013
Istituto di Biostrutture e Bioimmagini - IBB - Sede Napoli
Istituto di Cristallografia - IC
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/20.500.14243/277316
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