Decoding Surface Fingerprints for Protein-Ligand Interactions

Igashov, Ilia; Jamasb, Arian R.; Sadek, Ahmed K.; Sverrisson, Freyr; Schneuing, Arne; Lió, Píetro; Blundell, Tom L.; Bronstein, Michael M.; Correia, Bruno E.

doi:10.1101/2022.04.26.489341

Cited by 7 publications

(8 citation statements)

References 64 publications

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“…Experimentally, this is achieved by performing high throughput screens and hit validation followed by lead optimization. Computational approaches such as binding pocket identification [127][128][129][130][131][132] , protein-ligand docking [133][134][135][136][137][138] , virtual screening [139][140][141] , and ligand binding free energy calculations 94,95,142,143 can also be applied and have been shown to be helpful in this area. With a combination of computational and experimental approaches, rational discovery of molecular glues may indeed be feasible, even though the best and the most effective solution to this task is yet to be determined.…”

Section: Concluding Discussionmentioning

confidence: 99%

Protein–protein interfaces in molecular glue-induced ternary complexes: classification, characterization, and prediction

et al. 2023

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Section: Concluding Discussionmentioning

confidence: 99%

Protein–protein interfaces in molecular glue-induced ternary complexes: classification, characterization, and prediction

et al. 2023

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“…AlphaFold [223], AlphaFold2 [128], RosettaFold [9], RosettaFold2 [10], RFAA [145], EigenFold [126], RFdiffusion [267], Chroma [110], ESMFold [157], HelixFold-Single [60] Protein Co-Design Generative Chroma [110], RFdiffusion [267], PROTSEED [226] Pretraining Mixed ProtTrans [57], ProtGPT2 [63], GearNet [303], PromptProtein [264], ProFSA [71], DrugCLIP [72], ESM-1b [208], ESM2 [157], Guo et al [88] Mol + Mol Linker Design Generative DiffLinker [107], DeLinker [108], 3DLinker [103] Chemical Reaction Generative OA-ReactDiff [49], TSNet [112] Mol + Protein Ligand Binding Affinity Prediction Non-Generative TargetDiff [86], MaSIF [68], GET [143], ProtNet [257], HGIN [304], BindNet [62] Protein-Ligand Docking Mixed EquiBind [232], DiffDock [41], TankBind [170], DESERT [169], FABind [193] Pocket-Based Mol Sampling Mixed Pocket2Mol [194], TargetDiff [86], SBDD [172], FLAG [302] Protein + Protein Protein Interface Prediction Non-Generative DeepInteract <...…”

Section: Physicsmentioning

confidence: 99%

“…Mol + Mol ZINC [234] 727K Linker Design 3DLinker [103] CASF [235] 0.28K Linker Design DeLinker [108] GEOM [8] 450K Linker Design DiffLinker [107] SN2-TS [112] 0.11K Chemical Reaction TSNet [112] Transition1x [217] 9.6M Chemical Reaction OA-ReactDiff [49] Mol + Protein…”

Section: Dataset # Sample Task Benchmarkmentioning

confidence: 99%

Single-cell atlas of a non-human primate reveals new pathogenic mechanisms of COVID-19

Han

Wei

Liu

et al. 2020

Preprint

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Stopping COVID-19 is a priority worldwide. Understanding which cell types are targeted by SARS-CoV-2 virus, whether interspecies differences exist, and how variations in cell state influence viral entry is fundamental for accelerating therapeutic and preventative approaches. In this endeavor, we profiled the transcriptome of nine tissues from a Macaca fascicularis monkey at single-cell resolution. The distribution of SARS-CoV-2 facilitators, ACE2 and TMRPSS2, in different cell subtypes showed substantial heterogeneity across lung, kidney, and liver. Through co-expression analysis, we identified immunomodulatory proteins such as IDO2 and ANPEP as potential SARS-CoV-2 targets responsible for immune cell exhaustion. Furthermore, single-cell chromatin accessibility analysis of the kidney unveiled a plausible link between IL6-mediated innate immune responses aiming to protect tissue and enhanced ACE2 expression that could promote viral entry. Our work constitutes a unique resource for understanding the physiology and pathophysiology of two phylogenetically close species, which might guide in the development of therapeutic approaches in humans.Bullet pointsWe generated a single-cell transcriptome atlas of 9 monkey tissues to study COVID-19.ACE2+TMPRSS2+ epithelial cells of lung, kidney and liver are targets for SARS-CoV-2.ACE2 correlation analysis shows IDO2 and ANPEP as potential therapeutic opportunities.We unveil a link between IL6, STAT transcription factors and boosted SARS-CoV-2 entry.

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“…116,117 Besides, graph edits are also applied for the single-step retrosynthesis task, where target molecules are transformed into reactants by applying an iterative refining procedure. For example, Igashov et al 118 generate the reactants for the target molecule by applying diffusion models on the graph level. Transition kernels that bridge the distribution between product structures and reactant structures alter the connectivity and atom types directly on the product structure.…”

Section: Graphmentioning

confidence: 99%

Exploring Chemical Reaction Space with Machine Learning Models: Representation and Feature Perspective

Ding,

Qiang,

Chen

et al. 2024

J. Chem. Inf. Model.

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Chemical reactions serve as foundational building blocks for organic chemistry and drug design. In the era of large AI models, data-driven approaches have emerged to innovate the design of novel reactions, optimize existing ones for higher yields, and discover new pathways for synthesizing chemical structures comprehensively. To effectively address these challenges with machine learning models, it is imperative to derive robust and informative representations or engage in feature engineering using extensive data sets of reactions. This work aims to provide a comprehensive review of established reaction featurization approaches, offering insights into the selection of representations and the design of features for a wide array of tasks. The advantages and limitations of employing SMILES, molecular fingerprints, molecular graphs, and physics-based properties are meticulously elaborated. Solutions to bridge the gap between different representations will also be critically evaluated. Additionally, we introduce a new frontier in chemical reaction pretraining, holding promise as an innovative yet unexplored avenue.

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Decoding Surface Fingerprints for Protein-Ligand Interactions

Cited by 7 publications

References 64 publications

Protein–protein interfaces in molecular glue-induced ternary complexes: classification, characterization, and prediction

Protein–protein interfaces in molecular glue-induced ternary complexes: classification, characterization, and prediction

Single-cell atlas of a non-human primate reveals new pathogenic mechanisms of COVID-19

Exploring Chemical Reaction Space with Machine Learning Models: Representation and Feature Perspective

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