Mapping the conformational transition in Src activation by cumulating the information from multiple molecular dynamics trajectories.

The Src-family kinases are allosteric enzymes that play a key role in the regulation of cell growth and proliferation. In response to cellular signals, they undergo large conformational changes to switch between distinct inactive and active states. A computational strategy for characterizing the conformational transition pathway is presented to bridge the inactive and active states of the catalytic domain of Hck. The information from a large number (78) of independent all-atom molecular dynamics trajectories with explicit solvent is combined together to assemble a connectivity map of the conformational transition. Two intermediate states along the activation pathways are identified, and their structural features are characterized. A coarse free-energy landscape is built in terms of the collective motions corresponding to the opening of the activation loop (A-loop) and the rotation of the alphaC helix. This landscape shows that the protein can adopt a multitude of conformations in which the A-loop is partially open, while the alphaC helix remains in the orientation characteristic of the inactive conformation. The complete transition leading to the active conformation requires a concerted movement involving further opening of the A-loop, the relative alignment of N-lobe and C-lobe, and the rotation of the alphaC helix needed to recruit the residues necessary for catalysis in the active site. The analysis leads to a dynamic view of the full-length kinase activation, whereby transitions of the catalytic domain to intermediate configurations with a partially open A-loop are permitted, even while the SH2-SH3 clamp remains fully engaged. These transitions would render Y416 available for the transphosphorylation event that ultimately locks down the active state. The results provide a broad framework for picturing the conformational transitions leading to kinase activation.