We propose a computational model for the study of maltose binding protein translocation across alpha-hemolysin nanopores. The phenomenological approach simplifies both the pore and the polypeptide chain; however it retains the basic structural protein-like properties of the maltose binding protein by promoting the correct formation of its native key interactions. By considering different observables characterising the channel blockade and molecule transport, we verified that MD simulations reproduce qualitatively the behaviour observed in a recent experiment. Simulations reveal that blockade events consist of a capture stage, to some extent related to the unfolding kinetics, and a single file translocation process in the channel. A threshold mechanics underlies the process activation with a critical force depending on the protein denaturation state. Finally, our results support the simple interpretation of translocation via first-passage statistics of a driven diffusion process of a single reaction coordinate.
Computational analysis of maltose binding protein translocation / Chinappi, Mauro; Cecconi, Fabio; Casciola, Carlo Massimo. - In: PHILOSOPHICAL MAGAZINE. - ISSN 1478-6435. - STAMPA. - 91:13-15(2011), pp. 2034-2048. [10.1080/14786435.2011.557670]
Computational analysis of maltose binding protein translocation
CHINAPPI, MAURO;CECCONI, FABIO;CASCIOLA, Carlo Massimo
2011
Abstract
We propose a computational model for the study of maltose binding protein translocation across alpha-hemolysin nanopores. The phenomenological approach simplifies both the pore and the polypeptide chain; however it retains the basic structural protein-like properties of the maltose binding protein by promoting the correct formation of its native key interactions. By considering different observables characterising the channel blockade and molecule transport, we verified that MD simulations reproduce qualitatively the behaviour observed in a recent experiment. Simulations reveal that blockade events consist of a capture stage, to some extent related to the unfolding kinetics, and a single file translocation process in the channel. A threshold mechanics underlies the process activation with a critical force depending on the protein denaturation state. Finally, our results support the simple interpretation of translocation via first-passage statistics of a driven diffusion process of a single reaction coordinate.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
