Abstract
Trigger factor (TF) is a chaperone, found in bacterial cells and chloroplasts, that interacts with nascent polypeptide chains to suppress aggregation. While its crystal structure has been resolved, the solution structure and dynamics are largely unknown. We performed multiple molecular dynamics simulations on Trigger factor in solution, and show that its tertiary domains display collective motions hinged about inter-domain linkers with minimal or no loss in secondary structure. Moreover, we find that isolated TF typically adopts a collapsed state, with the formation of domain pairs. This collapse of TF in solution is induced by hydrophobic interactions and stabilised by hydrophilic contacts. To determine the nature of the domain interactions, we analysed the hydrophobicity of the domain surfaces by using the hydrophobic probe method of Acharya et al. [1], [2], as the standard hydrophobicity scales predictions are limited due to the complex environment. We find that the formation of domain pairs changes the hydrophobic map of TF, making the N-terminal and arm2 domain pair more hydrophilic and the head and arm1 domain pair more hydrophobic. These insights into the dynamics and interactions of the TF domains are important to eventually understand chaperone-substrate interactions and chaperone function.
Highlights
Most proteins, synthesised as linear polypeptide chains in ribosomes, have to fold into specific and unique 3-D structures in order to function
On an IBM Power 6 machine each trajectory run with OPLS-AA parameters took a total of 432 CPU hours on 128 cores; each trajectory run with AMBER03 parameters took 525 hours on 64 cores; each trajectory run with AMBER03 parameters took 761 hours on 64 cores (45488 core hours)
The resulting trajectories give a good indication of the relaxation of Trigger factor (TF) towards a equilibrium, giving insight into the behaviour of TF in solution
Summary
Most proteins, synthesised as linear polypeptide chains in ribosomes, have to fold into specific and unique 3-D structures in order to function. The spontaneous unassisted folding process is highly prone to misfolding, leading to the formation of dysfunctional proteins and aggregates [3]. Molecular chaperones suppress these anomalies by interacting with the newly synthesised proteins by stabilising proteins in the cytosol or by maintaining the unfolded polypeptide chains for translocation through organelle membranes [4,5,6,7,8]. It is located in the cytosol as well as near the ribosome exit tunnel. TF is found in a dimer-monomer equilibrium [19,20,21,22,23,24] and supposedly interacts with full-length proteins in order to prevent aggregation [24,25]
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