Bertalan Kovács scite author profile

Parvulins or rotamases form a distinct group within peptidyl prolyl cis-trans isomerases. Their exact mode of action as well as the role of conserved residues in the family are still not unambiguously resolved. Using backbone S2 order parameters and NOEs as restraints, we have generated dynamic structural ensembles of three distinct parvulins, SaPrsA, TbPin1 and CsPinA. The resulting ensembles are in good agreement with the experimental data but reveal important differences between the three enzymes. The largest difference can be attributed to the extent of the opening of the substrate binding cleft, along which motional mode the three molecules occupy distinct regions. Comparison with a wide range of other available parvulin structures highlights structural divergence along the bottom of the binding cleft acting as a hinge during the opening-closing motion. In the prototype WW-domain containing parvulin, Pin1, this region is also important in forming contacts with the WW domain known to modulate enzymatic activity of the catalytic domain. We hypothesize that modulation of the extent and dynamics of the identified ‘breathing motion’ might be one of the factors responsible for functional differences in the distinct parvulin subfamilies.

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CoNSEnsX⁺ Webserver for the Analysis of Protein Structural Ensembles Reflecting Experimentally Determined Internal Dynamics

Dudola

Kovács

Gáspári

2017

J. Chem. Inf. Model.

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Ensemble-based models of protein structure and dynamics reflecting experimental parameters are increasingly used to obtain deeper understanding of the role of dynamics in protein function. Such ensembles differ substantially from those routinely deposited in the PDB and, consequently, require specialized validation and analysis methodology. Here we describe our completely rewritten online validation tool, CoNSEnsX, that offers a standardized way to assess the correspondence of such ensembles to experimental NMR parameters. The server provides a novel selection feature allowing a user-selectable set and weights of different parameters to be considered. This also offers an approximation of potential overfitting, namely, whether the number of conformers necessary to reflect experimental parameters can be reduced in the ensemble provided. The CoNSEnsX webserver is available at consensx.itk.ppke.hu . The corresponding Python source code is freely available on GitHub ( github.com/PPKE-Bioinf/consensx.itk.ppke.hu ).

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Ligand‐dependent intra‐ and interdomain motions in the PDZ12 tandem regulate binding interfaces in postsynaptic density protein‐95

2019

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The postsynaptic density protein‐95 (PSD‐95) regulates synaptic plasticity through interactions mediated by its peptide‐binding PDZ domains. The two N‐terminal PDZ domains of PSD‐95 form an autonomous structural unit, and their interdomain orientation and dynamics depend on ligand binding. To understand the mechanistic details of the effect of ligand binding, we generated conformational ensembles using available experimentally determined nuclear Overhauser effect interatomic distances and S2 order parameters. In our approach, the fast dynamics of the two domains is treated independently. We find that intradomain structural changes induced by ligand binding modulate the probability of the occurrence of specific domain–domain orientations. Our results suggest that the β2‐β3 loop in the PDZ domains is a key regulatory region, which influences both intradomain motions and supramodular rearrangement.

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Interdependence of intra- and inter-domain motions in the PSD-95 PDZ12 tandem

Kovács

Zajácz-Epresi

Gáspári

2019

Preprint

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PSD-95 is the most abundant scaffold protein in the postsynaptic density of neurons. Its two N-terminal PDZ domains form an autonomous structural unit and their interdomain orientation and dynamics was shown to be dependent on binding to various partner proteins. To understand the mechanistic details of the effect of ligand binding on interdomain structure and dynamics, we generated conformational ensembles using experimentally determined NOE interatomic distances and S 2 order parameters, available from the literature. In our approach no explicit restraints between the two domains were used and their fast dynamics was also treated independently. We found that intradomain structural changes induced by ligand binding have a profound effect on the interfaces where interdomain contacts can be formed, modulating the probability of the occurrence of specific domain-domain orientations. Our results suggest that the β2-β3 loop in the PDZ domains is a key regulatory region that, through interacting with the upstream residues of the C-terminal peptide ligand, influences both intradomain motions and supramodular rearrangement.

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Evaluation and Selection of Dynamic Protein Structural Ensembles with CoNSEnsX+

Dudola

Kovács

Gáspári

2020

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