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MD-IFP: Interaction Fingerprint analysis of Molecular Dynamics trajectories

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Description

The MD-IFP is a python workflow for the generation and analysis of protein-ligand (PL) and protein-protein (PP) interaction fingerprints from Molecular Dynamics trajectories. If used for the analysis of RAMD (Random Accelaration Molecular Dynamics) trajectories, it can help to investigate dissociation mechanisms by characterizing transition states as well as the determinants and hot-spots for dissociation. As such, the combined use of τRAMD and MD-IFP may assist the early stages of drug discovery campaigns for the design of new molecules or ligand optimization. <br><br>

Cite us

If you use or adapt MD-IFP for your own research projects please cite us.

D. B. Kokh, B. Doser, S. Richter, F. Ormersbach, X. Cheng , R.C. Wade "A Workflow for Exploring Ligand Dissociation from a Macromolecule: Efficient Random Acceleration Molecular Dynamics Simulation and Interaction Fingerprints Analysis of Ligand Trajectories" J. Chem Phys.(2020) 158 125102 doi: 10.1063/5.0019088. <br><br>

Publications of the method application:

  1. IFP analysis of dissociation trajectories for 3 compounds of HSP90 reported in the paper

    D. B. Kokh, B. Doser, S. Richter, F. Ormersbach, X. Cheng , R.C. Wade "A Workflow for Exploring Ligand Dissociation from a Macromolecule: Efficient Random Acceleration Molecular Dynamics Simulation and Interaction Fingerprints Analysis of Ligand Trajectories" J. Chem Phys.(2020) 153 125102 doi: 10.1063/5.0019088; https://arxiv.org/abs/2006.11066

    Results are implemented in Dissociation mechanisms of HSP90-small molecules

  2. Small compound unbinding from T4 lysozyme mutants

    A Nunes-Alves, DB Kokh, RC Wade "Ligand unbinding mechanisms and kinetics for T4 lysozyme mutants from τRAMD simulations", Current Research in Structural Biology 3, 106-111 https://doi.org/10.1016/j.crstbi.2021.04.001

  3. Application to two GPCR targets (embedded in a membrane):

    D. B. Kokh, R.C. Wade "G-Protein Coupled Receptor-Ligand Dissociation Rates and Mechanisms from τRAMD Simulations", doi: https://doi.org/10.1101/2021.06.20.449151

    Associated scripts and data can be downloaded at https://zenodo.org/record/5001884#.YM-rRmgzYuU

    Results are implemented in Dissociation mechanisms from M2 and β2 adrenergic receptors

  4. Application to Protein-Protein complexes:

    Results are implemented in Dissociation mechanisms of protein-protein complexes <br><br>

Packages requirements:

Python 3.x

Python Libraries:

  1. numpy; pandas; matplotlib; seaborn; sklearn; scipy;
  2. RDkit - only for the MD-IFP analysis of protein-ligand complexes
  3. ngview - used for visualization. Installation of ngview can be tricky, the following way may work: after installation of the Python envirenment, execute:
conda install -c conda-forge nglview=2.7.1

and then

jupyter-nbextension enable nglview --py --sys-prefix

If you don't need visualization, you can skip this, but JN must be edited accordingly.

  1. MDAnalysis Version 1.1.1 - (Important: an old module for H-bond analysis is currently used, it will be removed in version 2.0 ). Best is to use the MD-IFP.yml file to generate a python environment in anaconda (as shown below).

  2. Chimera - only for the scripts used for preprocessing pdb files (structure protonation and generation of the ligand mol2 file; not required if protonation and mol2 file are already prepared by a user)

Codes were written on Python 3.x and tested on Python 3.8

To configure environment in anaconda use:

conda env create -f MD-IFP.yml

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Acknowledgments

This open source software code was developed in part in the Human Brain Project, funded from the European Union’s Horizon 2020 Framework Programme for Research and Innovation under Specific Grant Agreements No. 785907 (Human Brain Project SGA2).