Sampling large conformational transitions: adenylate kinase as a testing ground

Seyler, Sean L.; Beckstein, Oliver

doi:10.1080/08927022.2014.919497

Cited by 41 publications

(55 citation statements)

References 169 publications

(478 reference statements)

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“…Here pathway divergence, already evident from the PC1-2 distribution of experimental conformers, contains information about the sequence of movements in a multi-step complex landscape; unbiased MD from unbound forms (Supplementary Fig. 6c) also hints to differences in the preferred forward/reverse paths as suggested for some proteins1. However, when asymmetry is low, comparison with the FELs from MD rather suggests the equivalence of forward/reverse routes: in the three cases examined, they appear to delimit not different linear paths, but rather an area in the conformational landscape that overlaps with the lowest energy passage connecting the end-state basins.…”

Section: Discussionmentioning

confidence: 76%

Prediction and validation of protein intermediate states from structurally rich ensembles and coarse-grained simulations

et al. 2016

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Protein conformational changes are at the heart of cell functions, from signalling to ion transport. However, the transient nature of the intermediates along transition pathways hampers their experimental detection, making the underlying mechanisms elusive. Here we retrieve dynamic information on the actual transition routes from principal component analysis (PCA) of structurally-rich ensembles and, in combination with coarse-grained simulations, explore the conformational landscapes of five well-studied proteins. Modelling them as elastic networks in a hybrid elastic-network Brownian dynamics simulation (eBDIMS), we generate trajectories connecting stable end-states that spontaneously sample the crystallographic motions, predicting the structures of known intermediates along the paths. We also show that the explored non-linear routes can delimit the lowest energy passages between end-states sampled by atomistic molecular dynamics. The integrative methodology presented here provides a powerful framework to extract and expand dynamic pathway information from the Protein Data Bank, as well as to validate sampling methods in general.

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Section: Discussionmentioning

confidence: 76%

Prediction and validation of protein intermediate states from structurally rich ensembles and coarse-grained simulations

et al. 2016

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“…97 Importantly, enhanced sampling methods can be employed to obtain equilibrium properties over longer timescales, including conformation changes underlying channel gating. [98][99][100][101] MD-based methods also exist to compute thermodynamic information that may be useful to correlate experimental observables such as single channel conductance or thermodynamics with structural conformational changes. 102,103 Because TRP channels are temperature sensitive, temperature-based ensemble methods, such as temperature replica exchange (typically coupled with Hamiltonian exchange), are of particular interest.…”

Section: Identifying a Trp Specific Thermosensormentioning

confidence: 99%

Understanding Thermosensitive Transient Receptor Potential Channels as Versatile Polymodal Cellular Sensors

et al. 2015

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Transient receptor potential (TRP) ion channels are eukaryotic polymodal sensors that function as molecular cellular signal integrators. TRP family members sense and are modulated by a wide array of inputs, including temperature, pressure, pH, voltage, chemicals, lipids, and other proteins. These inputs induce signal transduction events mediated by nonselective cation passage through TRP channels. In this review, we focus on the thermosensitive TRP channels and highlight the emerging view that these channels play a variety of significant roles in physiology and pathophysiology in addition to sensory biology. We attempt to use this viewpoint as a framework to understand the complexity and controversy of TRP channel modulation and ultimately suggest that the complex functional behavior arises inherently because this class of protein is exquisitely sensitive to many diverse and distinct signal inputs. To illustrate this idea, we primarily focus on TRP channel thermosensing. We also offer a structural, biochemical, biophysical, and computational perspective that may help to bring more coherence and consensus in understanding the function of this important class of proteins.

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“…The transition of ADK has been extensively studied with different computational methods . Abundant experimentally determined intermediate structures make it a suitable test case for validation.…”

Section: Resultsmentioning

confidence: 99%

Frustration-guided motion planning reveals conformational transitions in proteins

et al. 2017

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Proteins exist as conformational ensembles, exchanging between substates to perform their function. Advances in experimental techniques yield unprecedented access to structural snapshots of their conformational landscape. However, computationally modeling how proteins use collective motions to transition between substates is challenging owing to a rugged landscape and large energy barriers. Here, we present a new, robotics-inspired motion planning procedure called dCC-RRT that navigates the rugged landscape between substates by introducing dynamic, interatomic constraints to modulate frustration. The constraints balance non-native contacts and flexibility, and instantaneously redirect the motion towards sterically favorable conformations. On a test set of eight proteins determined in two conformations separated by, on average, 7.5 Å root mean square deviation (RMSD), our pathways reduced the Cα atom RMSD to the goal conformation by 78%, outperforming peer methods. We then applied dCC-RRT to examine how collective, small-scale motions of four side-chains in the active site of cyclophilin A propagate through the protein. dCC-RRT uncovered a spatially contiguous network of residues linked by steric interactions and collective motion connecting the active site to a recently proposed, non-canonical capsid binding site 25 Å away, rationalizing NMR and multi-temperature crystallography experiments. In all, dCC-RRT can reveal detailed, all-atom molecular mechanisms for small and large amplitude motions. Source code and binaries are freely available at https://github.com/ExcitedStates/KGS/.

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Sampling large conformational transitions: adenylate kinase as a testing ground

Cited by 41 publications

References 169 publications

Prediction and validation of protein intermediate states from structurally rich ensembles and coarse-grained simulations

Prediction and validation of protein intermediate states from structurally rich ensembles and coarse-grained simulations

Understanding Thermosensitive Transient Receptor Potential Channels as Versatile Polymodal Cellular Sensors

Frustration-guided motion planning reveals conformational transitions in proteins

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