Improvement of the Treatment of Loop Structures in the UNRES Force Field by Inclusion of Coupling between Backbone- and Side-Chain-Local Conformational States

Krupa, Paweł; Sieradzan, Adam K.; Rackovsky, S.; Baranowski, Maciej; Ołldziej, Stanisław; Scheraga, Harold A.; Liwo, Adam; Czaplewski, Cezary

doi:10.1021/ct4004977

Cited by 30 publications

(66 citation statements)

References 76 publications

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“…UNRES force field managed to achieve comparable results to the most of the TBM methods also for other 'FM' targets and domains, such as T0763-D1, T0771-D1, T0775-D2, T0793-D2, T0820-D1 and T0834-D2. It is also remarkable that, in CASP11, there is only a small difference between the ranking of our 'model 1's' and our best models indicating that the UNRES force field, supplemented with the recently introduced terms corresponding to the coupling of the backboneand side-chain-local interactions (Krupa et al, 2013;Sieradzan et al, 2015), enables us to select the most native-like predictions out of the five models more accurately than the previous version of the force field used in CASP10. The better overall performance of our approach in CASP11 compared with previous CASP exercises was achieved because of recent addition of the new potentials coupling the backbone-local and sidechain-local conformational states.…”

Section: Resultsmentioning

confidence: 85%

“…U ssbond is the disulfide bond formation potential calculated over all possible permutations of disulfide bonds (nss). The U SCÀcorr terms are new knowledge-and physics-based side-chain backbone correlation potentials (Krupa et al, 2013;Sieradzan et al, 2015) recently introduced to the UNRES force field, which improved the correctness of secondary-structure and loop modeling with the UNRES force field.…”

Section: Unres Representation Of Polypeptide Chainmentioning

confidence: 99%

“…These targets represented all structural classes. We used the newest version of the UNRES force field supplemented with energy terms corresponding to the coupling between backbone-local and sidechainlocal conformational states (Krupa et al, 2013;Sieradzan et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

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Performance of protein-structure predictions with the physics-based UNRES force field in CASP11

et al. 2016

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Summary: Participating as the Cornell-Gdansk group, we have used our physics-based coarsegrained UNited RESidue (UNRES) force field to predict protein structure in the 11th Community Wide Experiment on the Critical Assessment of Techniques for Protein Structure Prediction (CASP11). Our methodology involved extensive multiplexed replica exchange simulations of the target proteins with a recently improved UNRES force field to provide better reproductions of the local structures of polypeptide chains. All simulations were started from fully extended polypeptide chains, and no external information was included in the simulation process except for weak restraints on secondary structure to enable us to finish each prediction within the allowed 3-week time window. Because of simplified UNRES representation of polypeptide chains, use of enhanced sampling methods, code optimization and parallelization and sufficient computational resources, we were able to treat, for the first time, all 55 human prediction targets with sizes from 44 to 595 amino acid residues, the average size being 251 residues. Complete structures of six singledomain proteins were predicted accurately, with the highest accuracy being attained for the T0769, for which the CaRMSD was 3.8 Å for 97 residues of the experimental structure. Correct structures were also predicted for 13 domains of multi-domain proteins with accuracy comparable to that of the best template-based modeling methods. With further improvements of the UNRES force field that are now underway, our physics-based coarse-grained approach to protein-structure prediction will eventually reach global prediction capacity and, consequently, reliability in simulating protein structure and dynamics that are important in biochemical processes. Availability and Implementation: Freely available on the web at

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Section: Resultsmentioning

confidence: 85%

Section: Unres Representation Of Polypeptide Chainmentioning

confidence: 99%

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Performance of protein-structure predictions with the physics-based UNRES force field in CASP11

et al. 2016

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“…28,29 The terms U b and U rot are the virtual-angle bending and side-chain rotamer potentials, respectively, and the term U bond accounts for backbone and side-chain virtual-bond stretching; 4,30 recently, 31 we extended the backbone virtual-bond stretching term to account for the trans−cis transition of peptide groups. The terms U corr (m) and U turn (m) correspond to the correlations (of order m) between peptide-group electrostatic and backbone local interactions; 21,22 the terms U turn (m) (the "turn" terms) involve consecutive segments of the chain.…”

Section: Journal Of Chemical Information and Modelingmentioning

confidence: 99%

Prediction of Protein Structure by Template-Based Modeling Combined with the UNRES Force Field

Krupa

Mozolewska

Joo³

et al. 2015

J. Chem. Inf. Model.

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A new approach to the prediction of protein structures that uses distance and backbone virtual-bond dihedral angle restraints derived from template-based models and simulations with the united residue (UNRES) force field is proposed. The approach combines the accuracy and reliability of template-based methods for the segments of the target sequence with high similarity to those having known structures with the ability of UNRES to pack the domains correctly. Multiplexed replica-exchange molecular dynamics with restraints derived from template-based models of a given target, in which each restraint is weighted according to the accuracy of the prediction of the corresponding section of the molecule, is used to search the conformational space, and the weighted histogram analysis method and cluster analysis are applied to determine the families of the most probable conformations, from which candidate predictions are selected. To test the capability of the method to recover template-based models from restraints, five single-domain proteins with structures that have been well-predicted by template-based methods were used; it was found that the resulting structures were of the same quality as the best of the original models. To assess whether the new approach can improve template-based predictions with incorrectly predicted domain packing, four such targets were selected from the CASP10 targets; for three of them the new approach resulted in significantly better predictions compared with the original template-based models. The new approach can be used to predict the structures of proteins for which good templates can be found for sections of the sequence or an overall good template can be found for the entire sequence but the prediction quality is remarkably weaker in putative domain-linker regions.

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“…3 The SBD-closed (ADP-bound) structure of the DnaK Hsp70 chaperone from E. coli was determined by Zuiderweg and coworkers 10 by NMR spectroscopy (PDB: 2KHO). Recently, 11 we carried out molecular dynamics simulations, using the coarse-grained UNRES force field 12-15 developed in our laboratory, of the conformational transition of DnaK, starting from the SBD-closed 2KHO structure. We determined a probable structure of the SBD-open conformation 11 , which was unknown at the time, and which turned out to be very close to the x-ray structure of the SBD-open (ATP-bound) form of DnaK, which was determined by Mayer and coworkers 3 after the results of our simulations had been published.…”

Section: Introductionmentioning

confidence: 99%

Common functionally important motions of the nucleotide‐binding domain of Hsp70

et al. 2014

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The 70 kDa Heat Shock Proteins (Hsp70) are a family of molecular chaperones involved in protein folding, aggregate prevention, and protein disaggregation. They consist of the substrate binding domain (SBD) that binds client substrates, and the nucleotide-binding domain (NBD), whose cycles of nucleotide hydrolysis and exchange underpin the activity of the chaperone. To characterize the structure-function relationships that link the binding state of the NBD to its conformational behavior, we analyzed the dynamics of the NBD of the Hsp70 chaperone from Bos taurus (pdb 3C7N:B) by all-atom canonical molecular dynamics simulations. It was found that essential motions within the NBD fall into three major classes: the mutual class, reflecting tendencies common to all binding states, and the ADP- and ATP-unique classes, which reflect conformational trends that are unique to either the ADP- or ATP-bound states, respectively. ‘Mutual’ class motions generally describe ‘in-plane’ and/or ‘out-of-plane’ (‘scissor-like’) rotation of the subdomains within the NBD. This result is consistent with experimental nuclear magnetic resonance data on the NBD. The ‘Unique’ class motions target specific regions on the NBD, usually surface loops or sites involved in nucleotide-binding and are, therefore, expected to be involved in allostery and signal transmission. For all classes, and especially for those of the ‘Unique’ type, regions of enhanced mobility can be identified; these are termed ‘hot-spots,’ and their locations generally parallel those found by NMR spectroscopy. The presence of magnesium and potassium cations in the nucleotide-binding pocket was also found to influence the dynamics of the NBD significantly.

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Improvement of the Treatment of Loop Structures in the UNRES Force Field by Inclusion of Coupling between Backbone- and Side-Chain-Local Conformational States

Cited by 30 publications

References 76 publications

Performance of protein-structure predictions with the physics-based UNRES force field in CASP11

Performance of protein-structure predictions with the physics-based UNRES force field in CASP11

Prediction of Protein Structure by Template-Based Modeling Combined with the UNRES Force Field

Common functionally important motions of the nucleotide‐binding domain of Hsp70

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