CryptoSite: Expanding the Druggable Proteome by Characterization and Prediction of Cryptic Binding Sites

Cimermančič, Peter; Weinkam, Patrick; Rettenmaier, T.J.; Bichmann, Leon; Keedy, D.A.; Woldeyes, R.A.; Stroopinsky, Dina; Demerdash, Omar; Mitchell, Julie C.; Wells, James A.; Fraser, James S.; Šali, Andrej

doi:10.1016/j.jmb.2016.01.029

Cited by 191 publications

(319 citation statements)

References 65 publications

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“…the thermal shift assay) (102), NMR-based fragment screens (103), competitive binding screens when a weak ligand is available (69), and affinity-based selection are all popular techniques (104). Other techniques to identify cryptic binding sites may also identify novel pockets on protein surfaces that could be targeted by degradation technologies (105, 106). …”

Section: Discussionmentioning

confidence: 99%

Targeted Protein Degradation by Small Molecules

Bondeson

Crews²

2017

Annu. Rev. Pharmacol. Toxicol.

150

142

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Protein homeostasis networks are highly regulated systems responsible for maintaining the health and productivity of cells. Whereas therapeutics have been developed to disrupt protein homeostasis, more recently identified techniques have been used to repurpose homeostatic networks to effect degradation of disease-relevant proteins. Here, we review recent advances in the use of small molecules to degrade proteins in a selective manner. First, we highlight all-small-molecule techniques with direct clinical application. Second, we describe techniques that may find broader acceptance in the biomedical research community that require little or no synthetic chemistry. In addition to serving as innovative research tools, these new approaches to control intracellular protein levels offer the potential to develop novel therapeutics targeting proteins that are not currently pharmaceutically vulnerable.

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Section: Discussionmentioning

confidence: 99%

Targeted Protein Degradation by Small Molecules

Bondeson

Crews²

2017

Annu. Rev. Pharmacol. Toxicol.

150

142

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“…To demonstrate how conformational changes impact druggability, we applied our druggability prediction models to two systems containing cryptic binding sites. [38][39][40] It has been reported that appropriately sized pockets of the biologically relevant drug targets are necessary for the strong binding of drug-sized ligands. 41,42 For the target proteins that are considered tractable but less-druggable, it is of interest to identify their cryptic sites and to exploit those sites to boost the druggability of the drug targets.…”

Section: Resultsmentioning

confidence: 99%

Druggability Assessment in TRAPP using Machine Learning Approaches

Yuan

Han

Richter

et al. 2019

Preprint

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Accurate protein druggability predictions are important for the selection of drug targets in the early stages of drug discovery. Due to the flexible nature of proteins, the druggability of a binding pocket may vary due to conformational changes. We have therefore developed two statistical models, a logistic regression model (TRAPP-LR) and a convolutional neural network model (TRAPP-CNN), for predicting druggability and how it varies with changes in the spatial and physicochemical properties of a binding pocket. These models are integrated into TRAPP (TRAnsient Pockets in Proteins), a tool for the analysis of binding pocket variations along a protein motion trajectory.The models, which were trained on publicly available and self-augmented data sets, show equivalent or superior performance to existing methods on test sets of protein crystal structures, and have sufficient sensitivity to identify potentially druggable protein conformations in trajectories from molecular dynamics simulations. Visualization of the evidence for the decisions of the models in TRAPP facilitates identification of the factors affecting the druggability of protein binding pockets.

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“…Identifying these cryptic sites could offer new druggable sites on established drug targets, provide a means to inhibit proteins that are currently considered undruggable, or enable the enhancement of desirable activities. 3,4 Raltegravir, for example, is a first-line treatment for HIV infection 5 that inhibits HIV integrase by binding a cryptic pocket. However, the population of a given excited state is often too low to detect experimentally unless a binding partner that stabilizes it is present.…”

Section: Introductionmentioning

confidence: 99%

Cooperative changes in solvent exposure identify cryptic pockets, conformational switches, and allosteric coupling

Porter¹,

Moeder²,

Sibbald³

et al. 2018

Preprint

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Conformational changes can dramatically alter a protein's function by changing the surfaces that are accessible to interact with binding partners. However, it is often difficult to hone in on the most relevant conformational changes from the cartesian coordinates of atoms on the protein's surface. Instead, we describe a protein's surface in terms of groups of residues that undergo cooperative changes in their solvent exposure. We term these groups exposons. We demonstrate that Markov state models (MSMs) elegantly identify the conformational transitions that give rise to an exposon, enabling users to rapidly find the most interesting conformational changes in their system. For example, this approach readily identifies previously-known cryptic allosteric sites and other functionally-relevant conformational transitions. Moreover, it predicts a cryptic allosteric site in an important target for combating antibiotic resistance that lacks known cryptic pockets. Experimental tests confirm that targeting this site reduces catalytic efficiency 15-fold.

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CryptoSite: Expanding the Druggable Proteome by Characterization and Prediction of Cryptic Binding Sites

Cited by 191 publications

References 65 publications

Targeted Protein Degradation by Small Molecules

Targeted Protein Degradation by Small Molecules

Druggability Assessment in TRAPP using Machine Learning Approaches

Cooperative changes in solvent exposure identify cryptic pockets, conformational switches, and allosteric coupling

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