MARTINI-Based Protein-DNA Coarse-Grained HADDOCKing

Honorato, Rodrigo Vargas; Roel‐Touris, Jorge; Bonvin, Alexandre

doi:10.3389/fmolb.2019.00102

Cited by 29 publications

(34 citation statements)

References 38 publications

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“…Given the improvements in accuracy in Martini 3, another key advantage of CG models in general is their computational performance. For instance, Martini CG based docking of biomolecular complexes can be around one order of magnitude faster compared to atomistic models, as recently demonstrated for the Haddock program 79,80 . Benchmarks tests performed with the program package Gromacs (version 2018) 81 showed that Martini based MD simulations of protein-ligand systems can be 110-350 times faster than all-atom simulations, with the performance gain increasing with growing system size (see Supplementary Discussion and Supplementary Table 2).…”

Section: Discussionmentioning

confidence: 83%

Protein–ligand binding with the coarse-grained Martini model

et al. 2020

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The detailed understanding of the binding of small molecules to proteins is the key for the development of novel drugs or to increase the acceptance of substrates by enzymes. Nowadays, computer-aided design of protein-ligand binding is an important tool to accomplish this task. Current approaches typically rely on high-throughput docking essays or computationally expensive atomistic molecular dynamics simulations. Here, we present an approach to use the recently re-parametrized coarse-grained Martini model to perform unbiased millisecond sampling of protein-ligand interactions of small drug-like molecules. Remarkably, we achieve high accuracy without the need of any a priori knowledge of binding pockets or pathways. Our approach is applied to a range of systems from the wellcharacterized T4 lysozyme over members of the GPCR family and nuclear receptors to a variety of enzymes. The presented results open the way to high-throughput screening of ligand libraries or protein mutations using the coarse-grained Martini model.

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Section: Discussionmentioning

confidence: 83%

Protein–ligand binding with the coarse-grained Martini model

et al. 2020

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“…However, the oxDNA/oxRNA models only allow for representation of nucleic acids alone, limiting their scope of usability. While there have been coarse-grained simulation models developed for protein-DNA interactions, [31][32][33][34][35][36][37] none are able to be directly used with the oxDNA model. The development of an efficient tool compatible with oxDNA would allow for efficient study of arbitrary protein-DNA complexes.…”

Section: Introductionmentioning

confidence: 99%

Coarse-grained nucleic acid–protein model for hybrid nanotechnology

2021

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“…Compared with the structures predicted by the all atom model, it has been confirmed that the MARTINI force field not only accelerates the simulation process by about three orders, but also preserves the characteristics of different amino acids, as the all atom model also does. The comparisons between the structures predicted by the MARTINI CG and all atom models can be also seen for a peptide-bilayer system 32 , DNA 33 , and DNA–protein complexes 34 , which show good reproductively of the CG model to those by the AA model.…”

Section: Introductionmentioning

confidence: 79%

Exploring the most stable aptamer/target molecule complex by the stochastic tunnelling-basin hopping-discrete molecular dynamics method

Chen

et al. 2021

Sci Rep

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The stochastic tunnelling-basin hopping-discrete molecular dynamics (STUN-BH-DMD) method was applied to the search for the most stable biomolecular complexes in water by using the MARTINI coarse-grained (CG) model. The epithelial cell adhesion molecule (EpCAM, PDB code: 4MZV) was used as an EpCAM adaptor for an EpA (AptEpA) benchmark target molecule. The effects of two adsorption positions on the EpCAM were analysed, and it is found that the AptEpA adsorption configuration located within the EpCAM pocket-like structure is more stable and the energy barrier is lower due to the interaction with water. By the root mean square deviation (RMSD), the configuration of EpCAM in water is more conservative when the AptEpA binds to EpCAM by attaching to the pocket space of the EpCAM dimer. For AptEpA, the root mean square fluctuation (RMSF) analysis result indicates Nucleobase 1 and Nucleobase 2 display higher flexibility during the CGMD simulation. Finally, from the binding energy contour maps and histogram plots of EpCAM and each AptEpA nucleobase, it is clear that the binding energy adsorbed to the pocket-like structure is more continuous than that energy not adsorbed to the pocket-like structure. This study has proposed a new numerical process for applying the STUN-BH-DMD with the CG model, which can reduce computational details and directly find a more stable AptEpA/EpCAM complex in water.

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MARTINI-Based Protein-DNA Coarse-Grained HADDOCKing

Cited by 29 publications

References 38 publications

Protein–ligand binding with the coarse-grained Martini model

Protein–ligand binding with the coarse-grained Martini model

Coarse-grained nucleic acid–protein model for hybrid nanotechnology

Exploring the most stable aptamer/target molecule complex by the stochastic tunnelling-basin hopping-discrete molecular dynamics method

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