Abstract
We characterize the conformational dynamics and substrate selectivity of the signal recognition particle (SRP) using a thermodynamic free energy cycle approach and microsecond timescale molecular dynamics simulations. The SRP is a central component of the co-translational protein targeting machinery that binds to the N-terminal signal peptide (SP) of nascent proteins. We determined the shift in relative conformational stability of the SRP upon substrate binding to quantify allosteric coupling between SRP domains. In particular, for dipeptidyl aminopeptidase, an SP that is recognized by the SRP for co-translational targeting, it is found that substrate binding induces substantial changes in the SRP toward configurations associated with targeting of the nascent protein, and it is found that the changes are modestly enhanced by a mutation that increases the hydrophobicity of the SP. However, for alkaline phosphatase, an SP that is recognized for post-translational targeting, substrate binding induces the reverse change in the SRP conformational distribution away from targeting configurations. Microsecond timescale trajectories reveal the intrinsic flexibility of the SRP conformational landscape and provide insight into recent single molecule studies by illustrating that 10-nm lengthscale changes between FRET pairs occur via the rigid-body movement of SRP domains connected by the flexible linker region. In combination, these results provide direct evidence for the hypothesis that substrate-controlled conformational switching in the SRP provides a mechanism for discriminating between different SPs and for connecting substrate binding to downstream steps in the protein targeting pathway.
Highlights
The signal recognition particle (SRP) is a central component of the co-translational protein targeting pathway
As explained under “Computational Methods,” harmonic restraints are employed in the free energy (FE) calculations to limit the ensemble of sampled configurations for the SRP to those associated with either the syn or anti conformations that are observed in the experimental crystal structures [19, 20]
We note that a more common implementation of the thermodynamic cycle approach is to first assume that the different conformations of the biomolecule correspond to basins of stability that are separated by a FE barrier and to fully sample the configuration space associated with those basins of stability
Summary
The SRP is a central component of the co-translational protein targeting pathway. Results: Long timescale computer simulations reveal shifts in the SRP conformational distribution upon nascent protein binding. Microsecond timescale trajectories reveal the intrinsic flexibility of the SRP conformational landscape and provide insight into recent single molecule studies by illustrating that 10-nm lengthscale changes between FRET pairs occur via the rigid-body movement of SRP domains connected by the flexible linker region In combination, these results provide direct evidence for the hypothesis that substratecontrolled conformational switching in the SRP provides a mechanism for discriminating between different SPs and for connecting substrate binding to downstream steps in the protein targeting pathway. We use free energy (FE) calculations and microsecond timescale trajectories to investigate the coupling between SP binding and SRP conformational dynamics and to provide new insight into the role of SP binding in co-translational protein targeting Both structural [12,13,14,15,16,17,18,19,20,21] and biochemical work [22,23,24] suggest that the SRP exhibits multiple stable conformations that are important for protein targeting. Throughout this paper, we refer to these two conformations as syn and anti, indicating the relative orientation of the SRP RNA and the NG domain
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