Predicting locations of cryptic pockets from single protein structures using the PocketMiner graph neural network

Meller, Artur; Ward, Michael D.; Borowsky, Jonathan; Kshirsagar, Meghana; Lotthammer, Jeffrey M.; Oviedo, Felipe; Ferres, Juan M. Lavista; Bowman, Gregory R.

doi:10.1038/s41467-023-36699-3

Cited by 45 publications

(37 citation statements)

References 77 publications

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“…In those cases, AF predicts a structure with less than 1.2 Å root-mean-square deviation (RMSD) to the holo structure in the cryptic site (i.e., using all heavy atoms within 5 Å of where the cryptic ligand binds for the RMSD calculation). Interestingly, AlphaFold generates open states of the Niemann-Pick C2 Protein that were not discovered in 2 μs of adaptive sampling simulations (Figure B) . However, AlphaFold’s ensemble of TEM β-lactamase structures does not include any open states where the Horn or omega pockets are open (Figure S1).…”

Section: Resultsmentioning

confidence: 99%

“…This result makes PM-II an exception to a general trend. We have found that many cryptic pockets can be discovered with a handful of simulations of intermediate length (i.e., 40 ns) . Furthermore, significant progress has been made in developing algorithms for cryptic pocket discovery, including Markov state models, , enhanced sampling strategies like SWISH, or adaptive sampling approaches like FAST .…”

Section: Discussionmentioning

confidence: 99%

“…Cryptic pockets, or pockets absent in ligand-free experimental structures, are a promising means to expand the scope of drug discovery. By one estimate, almost half of all structured domains lack obvious pockets in their experimental structures . These proteins have often been considered “undruggable”.…”

Section: Introductionmentioning

confidence: 99%

“…While this process has revealed cryptic pockets, it requires knowledge of a ligand a priori . Molecular dynamics simulations can reveal excited states with cryptic pockets that can then be used for structure-based drug design. , However, in certain cases, cryptic pockets may not be discovered by simulations because cryptic pocket opening motions may be slow (e.g., Niemann-Pick C2 Protein in Meller et al). Two classes of slow motions include side chain ring flipping events and secondary structure rearrangements which can both occur on microsecond and slower time scales.…”

Section: Introductionmentioning

confidence: 99%

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Accelerating Cryptic Pocket Discovery Using AlphaFold

Meller

Bhakat

Solieva

et al. 2023

J. Chem. Theory Comput.

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Cryptic pockets, or pockets absent in ligand-free, experimentally determined structures, hold great potential as drug targets. However, cryptic pocket openings are often beyond the reach of conventional biomolecular simulations because certain cryptic pocket openings involve slow motions. Here, we investigate whether AlphaFold can be used to accelerate cryptic pocket discovery either by generating structures with open pockets directly or generating structures with partially open pockets that can be used as starting points for simulations. We use AlphaFold to generate ensembles for 10 known cryptic pocket examples, including five that were deposited after AlphaFold's training data were extracted from the PDB. We find that in 6 out of 10 cases AlphaFold samples the open state. For plasmepsin II, an aspartic protease from the causative agent of malaria, AlphaFold only captures a partial pocket opening. As a result, we ran simulations from an ensemble of AlphaFold-generated structures and show that this strategy samples cryptic pocket opening, even though an equivalent amount of simulations launched from a ligand-free experimental structure fails to do so. Markov state models (MSMs) constructed from the AlphaFold-seeded simulations quickly yield a free energy landscape of cryptic pocket opening that is in good agreement with the same landscape generated with well-tempered metadynamics. Taken together, our results demonstrate that AlphaFold has a useful role to play in cryptic pocket discovery but that many cryptic pockets may remain difficult to sample using AlphaFold alone.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Accelerating Cryptic Pocket Discovery Using AlphaFold

Meller

Bhakat

Solieva

et al. 2023

J. Chem. Theory Comput.

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“…Next, inspired by recent success in capturing cryptic pocket formation in molecular dynamics simulations, ( Hollingsworth et al, 2019 ; Sztain et al, 2021 ; Zimmerman et al, 2021 ; Cruz et al, 2022 ; Meller et al, 2023b ; Meller et al, 2023c ), we tested whether simulations launched from the AF structure could reveal cryptic pockets that encompass the flap or the hinge. We used an adaptive sampling algorithm FAST ( Zimmerman and Bowman, 2015 ) to search for cryptic pockets.…”

Section: Resultsmentioning

confidence: 99%

Discovery of a cryptic pocket in the AI-predicted structure of PPM1D phosphatase explains the binding site and potency of its allosteric inhibitors

Meller

Oliveira

Davtyan

et al. 2023

Front. Mol. Biosci.

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Virtual screening is a widely used tool for drug discovery, but its predictive power can vary dramatically depending on how much structural data is available. In the best case, crystal structures of a ligand-bound protein can help find more potent ligands. However, virtual screens tend to be less predictive when only ligand-free crystal structures are available, and even less predictive if a homology model or other predicted structure must be used. Here, we explore the possibility that this situation can be improved by better accounting for protein dynamics, as simulations started from a single structure have a reasonable chance of sampling nearby structures that are more compatible with ligand binding. As a specific example, we consider the cancer drug target PPM1D/Wip1 phosphatase, a protein that lacks crystal structures. High-throughput screens have led to the discovery of several allosteric inhibitors of PPM1D, but their binding mode remains unknown. To enable further drug discovery efforts, we assessed the predictive power of an AlphaFold-predicted structure of PPM1D and a Markov state model (MSM) built from molecular dynamics simulations initiated from that structure. Our simulations reveal a cryptic pocket at the interface between two important structural elements, the flap and hinge regions. Using deep learning to predict the pose quality of each docked compound for the active site and cryptic pocket suggests that the inhibitors strongly prefer binding to the cryptic pocket, consistent with their allosteric effect. The predicted affinities for the dynamically uncovered cryptic pocket also recapitulate the relative potencies of the compounds (τb = 0.70) better than the predicted affinities for the static AlphaFold-predicted structure (τb = 0.42). Taken together, these results suggest that targeting the cryptic pocket is a good strategy for drugging PPM1D and, more generally, that conformations selected from simulation can improve virtual screening when limited structural data is available.

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Toward physics‐based precision medicine: Exploiting protein dynamics to design new therapeutics and interpret variants

Meller,

Kelly,

Smith

et al. 2024

Protein Science

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The goal of precision medicine is to utilize our knowledge of the molecular causes of disease to better diagnose and treat patients. However, there is a substantial mismatch between the small number of food and drug administration (FDA)‐approved drugs and annotated coding variants compared to the needs of precision medicine. This review introduces the concept of physics‐based precision medicine, a scalable framework that promises to improve our understanding of sequence–function relationships and accelerate drug discovery. We show that accounting for the ensemble of structures a protein adopts in solution with computer simulations overcomes many of the limitations imposed by assuming a single protein structure. We highlight studies of protein dynamics and recent methods for the analysis of structural ensembles. These studies demonstrate that differences in conformational distributions predict functional differences within protein families and between variants. Thanks to new computational tools that are providing unprecedented access to protein structural ensembles, this insight may enable accurate predictions of variant pathogenicity for entire libraries of variants. We further show that explicitly accounting for protein ensembles, with methods like alchemical free energy calculations or docking to Markov state models, can uncover novel lead compounds. To conclude, we demonstrate that cryptic pockets, or cavities absent in experimental structures, provide an avenue to target proteins that are currently considered undruggable. Taken together, our review provides a roadmap for the field of protein science to accelerate precision medicine.

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Predicting locations of cryptic pockets from single protein structures using the PocketMiner graph neural network

Cited by 45 publications

References 77 publications

Accelerating Cryptic Pocket Discovery Using AlphaFold

Accelerating Cryptic Pocket Discovery Using AlphaFold

Discovery of a cryptic pocket in the AI-predicted structure of PPM1D phosphatase explains the binding site and potency of its allosteric inhibitors

Toward physics‐based precision medicine: Exploiting protein dynamics to design new therapeutics and interpret variants

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