More Like this

1. Improving the generalizability of protein-ligand binding predictions with AI-Bind

   https://doi.org/10.1038/s41467-023-37572-z  

   Chatterjee, Ayan; Walters, Robin; Shafi, Zohair; Ahmed, Omair Shafi; Sebek, Michael; Gysi, Deisy; Yu, Rose; Eliassi-Rad, Tina; Barabási, Albert-László; Menichetti, Giulia (December 2023, Nature Communications)

   Identifying novel drug-target interactions is a critical and rate-limiting step in drug discovery. While deep learning models have been proposed to accelerate the identification process, here we show that state-of-the-art models fail to generalize to novel (i.e., never-before-seen) structures. We unveil the mechanisms responsible for this shortcoming, demonstrating how models rely on shortcuts that leverage the topology of the protein-ligand bipartite network, rather than learning the node features. Here we introduce AI-Bind, a pipeline that combines network-based sampling strategies with unsupervised pre-training to improve binding predictions for novel proteins and ligands. We validate AI-Bind predictions via docking simulations and comparison with recent experimental evidence, and step up the process of interpreting machine learning prediction of protein-ligand binding by identifying potential active binding sites on the amino acid sequence. AI-Bind is a high-throughput approach to identify drug-target combinations with the potential of becoming a powerful tool in drug discovery. 

   more » « less
2. What Makes GPCRs from Different Families Bind to the Same Ligand?

   https://doi.org/10.3390/biom12070863  

   Dankwah, Kwabena Owusu; Mohl, Jonathon E.; Begum, Khodeza; Leung, Ming-Ying (July 2022, Biomolecules)

   G protein-coupled receptors (GPCRs) are the largest class of cell-surface receptor proteins with important functions in signal transduction and often serve as therapeutic drug targets. With the rapidly growing public data on three dimensional (3D) structures of GPCRs and GPCR-ligand interactions, computational prediction of GPCR ligand binding becomes a convincing option to high throughput screening and other experimental approaches during the beginning phases of ligand discovery. In this work, we set out to computationally uncover and understand the binding of a single ligand to GPCRs from several different families. Three-dimensional structural comparisons of the GPCRs that bind to the same ligand revealed local 3D structural similarities and often these regions overlap with locations of binding pockets. These pockets were found to be similar (based on backbone geometry and side-chain orientation using APoc), and they correlate positively with electrostatic properties of the pockets. Moreover, the more similar the pockets, the more likely a ligand binding to the pockets will interact with similar residues, have similar conformations, and produce similar binding affinities across the pockets. These findings can be exploited to improve protein function inference, drug repurposing and drug toxicity prediction, and accelerate the development of new drugs. 

   more » « less
3. Essential Dynamics Ensemble Docking for Structure-Based GPCR Drug Discovery

   https://doi.org/10.3389/fmolb.2022.879212  

   McKay, Kyle; Hamilton, Nicholas B.; Remington, Jacob M.; Schneebeli, Severin T.; Li, Jianing (June 2022, Frontiers in Molecular Biosciences)

   The lack of biologically relevant protein structures can hinder rational design of small molecules to target G protein-coupled receptors (GPCRs). While ensemble docking using multiple models of the protein target is a promising technique for structure-based drug discovery, model clustering and selection still need further investigations to achieve both high accuracy and efficiency. In this work, we have developed an original ensemble docking approach, which identifies the most relevant conformations based on the essential dynamics of the protein pocket. This approach is applied to the study of small-molecule antagonists for the PAC1 receptor, a class B GPCR and a regulator of stress. As few as four representative PAC1 models are selected from simulations of a homology model and then used to screen three million compounds from the ZINC database and 23 experimentally validated compounds for PAC1 targeting. Our essential dynamics ensemble docking (EDED) approach can effectively reduce the number of false negatives in virtual screening and improve the accuracy to seek potent compounds. Given the cost and difficulties to determine membrane protein structures for all the relevant states, our methodology can be useful for future discovery of small molecules to target more other GPCRs, either with or without experimental structures. 

   more » « less
4. Artificial intelligence in the prediction of protein–ligand interactions: recent advances and future directions

   https://doi.org/10.1093/bib/bbab476  

   Dhakal, Ashwin; McKay, Cole; Tanner, John J; Cheng, Jianlin (January 2022, Briefings in Bioinformatics)

   Abstract New drug production, from target identification to marketing approval, takes over 12 years and can cost around $2.6 billion. Furthermore, the COVID-19 pandemic has unveiled the urgent need for more powerful computational methods for drug discovery. Here, we review the computational approaches to predicting protein–ligand interactions in the context of drug discovery, focusing on methods using artificial intelligence (AI). We begin with a brief introduction to proteins (targets), ligands (e.g. drugs) and their interactions for nonexperts. Next, we review databases that are commonly used in the domain of protein–ligand interactions. Finally, we survey and analyze the machine learning (ML) approaches implemented to predict protein–ligand binding sites, ligand-binding affinity and binding pose (conformation) including both classical ML algorithms and recent deep learning methods. After exploring the correlation between these three aspects of protein–ligand interaction, it has been proposed that they should be studied in unison. We anticipate that our review will aid exploration and development of more accurate ML-based prediction strategies for studying protein–ligand interactions. 

   more » « less
5. Accurate ligand–protein docking in CASP15 using the ClusPro LigTBM server

   https://doi.org/10.1002/prot.26587  

   Kotelnikov, Sergei; Ashizawa, Ryota; Popov, Konstantin_I; Khan, Omeir; Ignatov, Mikhail; Li, Stan_Xiaogang; Hassan, Mosavverul; Coutsias, Evangelos_A; Poda, Gennady; Padhorny, Dzmitry; et al (September 2023, Proteins: Structure, Function, and Bioinformatics)

   Abstract In the ligand prediction category of CASP15, the challenge was to predict the positions and conformations of small molecules binding to proteins that were provided as amino acid sequences or as models generated by the AlphaFold2 program. For most targets, we used our template‐based ligand docking program ClusPro ligTBM, also implemented as a public server available athttps://ligtbm.cluspro.org/. Since many targets had multiple chains and a number of ligands, several templates, and some manual interventions were required. In a few cases, no templates were found, and we had to use direct docking using the Glide program. Nevertheless, ligTBM was shown to be a very useful tool, and by any ranking criteria, our group was ranked among the top five best‐performing teams. In fact, all the best groups used template‐based docking methods. Thus, it appears that the AlphaFold2‐generated models, despite the high accuracy of the predicted backbone, have local differences from the x‐ray structure that make the use of direct docking methods more challenging. The results of CASP15 confirm that this limitation can be frequently overcome by homology‐based docking. 

   more » « less