Interface-aware molecular generative framework for protein-protein interaction modulators
Protein-protein interactions (PPIs) play a crucial role in numerous biochemical and biological processes. Although several structure-based molecular generative models have been developed, PPI interfaces and compounds targeting PPIs exhibit distinct physicochemical properties compared to traditional binding pockets and small-molecule drugs. As a result, generating compounds that effectively target PPIs, particularly by considering PPI complexes or interface hotspot residues, remains a significant challenge. In this work, we constructed a comprehensive dataset of PPI interfaces with active and inactive compound pairs. Based on this, we propose a novel molecular generative framework tailored to PPI interfaces, named GENiPPI. Our evaluation demonstrates that GENiPPI captures the implicit relationships between the PPI interfaces and the active molecules, and can generate novel compounds that target these interfaces. Moreover, GENiPPI can generate structurally diverse novel compounds with limited PPI interface modulators. To the best of our knowledge, this is the first exploration of a structure-based molecular generative model focused on PPI interfaces, which could facilitate the design of PPI modulators. The PPI interface-based molecular generative model enriches the existing landscape of structure-based (pocket/interface) molecular generative model.
The code in this repository is based on their source code release (https://github.com/AspirinCode/iPPIGAN and https://github.com/kiharalab/GNN_DOVE). If you find this code useful, please consider citing their work.
[2024/12/20] Available online Journal of Cheminformatics, 2024.
[2024/11/11] Accepted in Journal of Cheminformatics, 2024.
[2024/03/15] submission to Journal of Cheminformatics, 2024.
[2023/10/10] submission to bioRxiv, 2023.
Python==3.6
pytorch==1.7.1
torchvision==0.8.2
tensorflow==2.5
keras==2.2.2
RDKit==2020.09.1.0
HTMD==1.13.9
Multiwfn==3.7
moleculekit==0.6.7
https://github.com/rdkit/rdkit
https://github.com/Acellera/htmd
https://github.com/Acellera/moleculekit
conda env create -f environment.yml
OR
conda create --name GENiPPI python=3.6 conda
pip install -r requirements.txt
OR
conda config --add channels acellera
conda install -c acellera htmd=1.13.9
#pytorch==1.7.1
conda install pytorch==1.7.1 torchvision==0.8.2 torchaudio==0.7.2 cudatoolkit=11.0 -c pytorch
#keras
conda install keras==2.2.2
#the training model
# 0 : train
python train.py [File Index] 0
#example
python train.py 1 0
python train.py 2 0
...
#fine-tuning
# 1 : fine tuning
python train.py [File Index] 1
#example
python train.py 2 1
python train.py 3 1
python train.py 4 1
...
For the generation stage the model files are available. It is possible to use the ones that are generated during the training step or you can download the ones that we have already generated model files from Google Drive.
novel compound generation please follow notebook:
python gen_wgan.py
or
GENiPPI_generate.ipynb
Molecular Sets (MOSES), a benchmarking platform to support research on machine learning for drug discovery. MOSES implements several popular molecular generation models and provides a set of metrics to evaluate the quality and diversity of generated molecules. With MOSES, MOSES aim to standardize the research on molecular generation and facilitate the sharing and comparison of new models. https://github.com/molecularsets/moses
quantitative estimate of protein-protein interaction targeting drug-likeness
https://github.com/ohuelab/QEPPI
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Kosugi T, Ohue M. Quantitative estimate index for early-stage screening of compounds targeting protein-protein interactions. International Journal of Molecular Sciences, 22(20): 10925, 2021. doi: 10.3390/ijms222010925 Another QEPPI publication (conference paper)
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Kosugi T, Ohue M. Quantitative estimate of protein-protein interaction targeting drug-likeness. In Proceedings of The 18th IEEE International Conference on Computational Intelligence in Bioinformatics and Computational Biology (CIBCB 2021), 2021. doi: 10.1109/CIBCB49929.2021.9562931 (PDF) * © 2021 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for all other uses, in any current or future media, including reprinting/republishing this material for advertising or promotional purposes, creating new collective works, for resale or redistribution to servers or lists, or reuse of any copyrighted component of this work in other works.
calculate NPR and PMI descriptors
Chem.Descriptors3D.NPR1(mol)
Chem.Descriptors3D.NPR2(mol)
Chem.rdMolDescriptors.CalcPMI1
Chem.rdMolDescriptors.CalcPMI2
Chem.rdMolDescriptors.CalcPMI3
https://greglandrum.github.io/rdkit-blog/posts/2022-06-22-variability-of-pmi-descriptors.html
calculate PBF descriptors
Chem.rdMolDescriptors.CalcPBF(mol)
reference
Firth, N.C., Brown, N. and Blagg, J., 2012. Plane of best fit: a novel method to characterize the three-dimensionality of molecules. Journal of chemical information and modeling, 52(10), pp.2516-2525.
https://github.com/reymond-group/mhfp
https://github.com/reymond-group/faerun-python
pip install mhfp
pip install faerun
reference code
https://tmap.gdb.tools/?ref=gdb.unibe.ch#ex-chembl
Code is released under GNU AFFERO GENERAL PUBLIC LICENSE.
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Jianmin Wang, Jiashun Mao, Chunyan Li, Hongxin Xiang, Xun Wang, Shuang Wang, Zixu Wang, Yangyang Chen, Yuquan Li, Kyoung Tai No, Tao Song, Xiangxiang Zeng; Interface-aware molecular generative framework for protein-protein interaction modulators. J Cheminform (2024). doi: https://doi.org/10.1186/s13321-024-00930-0
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Jianmin Wang, Yanyi Chu, Jiashun Mao, Hyeon-Nae Jeon, Haiyan Jin, Amir Zeb, Yuil Jang, Kwang-Hwi Cho, Tao Song, Kyoung Tai No, De novo molecular design with deep molecular generative models for PPI inhibitors, Briefings in Bioinformatics, 2022;, bbac285, https://doi.org/10.1093/bib/bbac285
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J. Wang, P. Zhou, Z. Wang, W. Long, Y. Chen, K.T. No, D. Ouyang, J. Mao, X. Zeng, Diffusion-based generative drug-like molecular editing with chemical natural language, Journal of Pharmaceutical Analysis, https://doi.org/10.1016/j.jpha.2024.101137.