Src kinases play fundamental roles in several crucial cell processes. Their activity is tightly regulated by conformational transitions between the active and the inactive forms, which are carried out by complex protein structural rearrangements. Here, we present an in-depth study of such structural transitions coupling extensive all-atoms molecular dynamic simulations coupled to an algorithm able to drive the system between defined conformational states. Our results, in line with the available experimental data, confirm the complexity of such a process indicating the main molecular determinants involved. Moreover, the role of an Src inhibitor—able to bind to the protein inactive state—is discussed and compared with available experimental data.
Modelling the activation pathways in full-length Src kinase / Alba, Josephine; Montagna, Maria; D’Abramo, Marco. - In: BIOPHYSICA. - ISSN 2673-4125. - 1:2(2021), pp. 238-248. [10.3390/biophysica1020018]
Modelling the activation pathways in full-length Src kinase
Alba, Josephine;Montagna, Maria;D’Abramo, Marco
Ultimo
2021
Abstract
Src kinases play fundamental roles in several crucial cell processes. Their activity is tightly regulated by conformational transitions between the active and the inactive forms, which are carried out by complex protein structural rearrangements. Here, we present an in-depth study of such structural transitions coupling extensive all-atoms molecular dynamic simulations coupled to an algorithm able to drive the system between defined conformational states. Our results, in line with the available experimental data, confirm the complexity of such a process indicating the main molecular determinants involved. Moreover, the role of an Src inhibitor—able to bind to the protein inactive state—is discussed and compared with available experimental data.| File | Dimensione | Formato | |
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