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Novel Computational Approach to Predict Off-Target Interactions for Small Molecules

Most small molecule drugs interact with unintended, often unknown, biological targets and these off-target interactions may lead to both preclinical and clinical toxic events. Undesired off-target interactions are often not detected using current drug discovery assays, such as experimental polypharm...

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Autores principales: Rao, Mohan S., Gupta, Rishi, Liguori, Michael J., Hu, Mufeng, Huang, Xin, Mantena, Srinivasa R., Mittelstadt, Scott W., Blomme, Eric A. G., Van Vleet, Terry R.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Frontiers Media S.A. 2019
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7931946/
https://www.ncbi.nlm.nih.gov/pubmed/33693348
http://dx.doi.org/10.3389/fdata.2019.00025
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author Rao, Mohan S.
Gupta, Rishi
Liguori, Michael J.
Hu, Mufeng
Huang, Xin
Mantena, Srinivasa R.
Mittelstadt, Scott W.
Blomme, Eric A. G.
Van Vleet, Terry R.
author_facet Rao, Mohan S.
Gupta, Rishi
Liguori, Michael J.
Hu, Mufeng
Huang, Xin
Mantena, Srinivasa R.
Mittelstadt, Scott W.
Blomme, Eric A. G.
Van Vleet, Terry R.
author_sort Rao, Mohan S.
collection PubMed
description Most small molecule drugs interact with unintended, often unknown, biological targets and these off-target interactions may lead to both preclinical and clinical toxic events. Undesired off-target interactions are often not detected using current drug discovery assays, such as experimental polypharmacological screens. Thus, improvement in the early identification of off-target interactions represents an opportunity to reduce safety-related attrition rates during preclinical and clinical development. In order to better identify potential off-target interactions that could be linked to predictable safety issues, a novel computational approach to predict safety-relevant interactions currently not covered was designed and evaluated. These analyses, termed Off-Target Safety Assessment (OTSA), cover more than 7,000 targets (~35% of the proteome) and > 2,46,704 preclinical and clinical alerts (as of January 20, 2019). The approach described herein exploits a highly curated training set of >1 million compounds (tracking >20 million compound-structure activity relationship/SAR data points) with known in vitro activities derived from patents, journals, and publicly available databases. This computational process was used to predict both the primary and secondary pharmacological activities for a selection of 857 diverse small molecule drugs for which extensive secondary pharmacology data are readily available (456 discontinued and 401 FDA approved). The OTSA process predicted a total of 7,990 interactions for these 857 molecules. Of these, 3,923 and 4,067 possible high-scoring interactions were predicted for the discontinued and approved drugs, respectively, translating to an average of 9.3 interactions per drug. The OTSA process correctly identified the known pharmacological targets for >70% of these drugs, but also predicted a significant number of off-targets that may provide additional insight into observed in vivo effects. About 51.5% (2,025) and 22% (900) of these predicted high-scoring interactions have not previously been reported for the discontinued and approved drugs, respectively, and these may have a potential for repurposing efforts. Moreover, for both drug categories, higher promiscuity was observed for compounds with a MW range of 300 to 500, TPSA of ~200, and clogP ≥7. This computation also revealed significantly lower promiscuity (i.e., number of confirmed off-targets) for compounds with MW > 700 and MW<200 for both categories. In addition, 15 internal small molecules with known off-target interactions were evaluated. For these compounds, the OTSA framework not only captured about 56.8% of in vitro confirmed off-target interactions, but also identified the right pharmacological targets for 14 compounds as one of the top scoring targets. In conclusion, the OTSA process demonstrates good predictive performance characteristics and represents an additional tool with utility during the lead optimization stage of the drug discovery process. Additionally, the computed physiochemical properties such as clogP (i.e., lipophilicity), molecular weight, pKa and logS (i.e., solubility) were found to be statistically different between the approved and discontinued drugs, but the internal compounds were close to the approved drugs space in most part.
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spelling pubmed-79319462021-03-09 Novel Computational Approach to Predict Off-Target Interactions for Small Molecules Rao, Mohan S. Gupta, Rishi Liguori, Michael J. Hu, Mufeng Huang, Xin Mantena, Srinivasa R. Mittelstadt, Scott W. Blomme, Eric A. G. Van Vleet, Terry R. Front Big Data Big Data Most small molecule drugs interact with unintended, often unknown, biological targets and these off-target interactions may lead to both preclinical and clinical toxic events. Undesired off-target interactions are often not detected using current drug discovery assays, such as experimental polypharmacological screens. Thus, improvement in the early identification of off-target interactions represents an opportunity to reduce safety-related attrition rates during preclinical and clinical development. In order to better identify potential off-target interactions that could be linked to predictable safety issues, a novel computational approach to predict safety-relevant interactions currently not covered was designed and evaluated. These analyses, termed Off-Target Safety Assessment (OTSA), cover more than 7,000 targets (~35% of the proteome) and > 2,46,704 preclinical and clinical alerts (as of January 20, 2019). The approach described herein exploits a highly curated training set of >1 million compounds (tracking >20 million compound-structure activity relationship/SAR data points) with known in vitro activities derived from patents, journals, and publicly available databases. This computational process was used to predict both the primary and secondary pharmacological activities for a selection of 857 diverse small molecule drugs for which extensive secondary pharmacology data are readily available (456 discontinued and 401 FDA approved). The OTSA process predicted a total of 7,990 interactions for these 857 molecules. Of these, 3,923 and 4,067 possible high-scoring interactions were predicted for the discontinued and approved drugs, respectively, translating to an average of 9.3 interactions per drug. The OTSA process correctly identified the known pharmacological targets for >70% of these drugs, but also predicted a significant number of off-targets that may provide additional insight into observed in vivo effects. About 51.5% (2,025) and 22% (900) of these predicted high-scoring interactions have not previously been reported for the discontinued and approved drugs, respectively, and these may have a potential for repurposing efforts. Moreover, for both drug categories, higher promiscuity was observed for compounds with a MW range of 300 to 500, TPSA of ~200, and clogP ≥7. This computation also revealed significantly lower promiscuity (i.e., number of confirmed off-targets) for compounds with MW > 700 and MW<200 for both categories. In addition, 15 internal small molecules with known off-target interactions were evaluated. For these compounds, the OTSA framework not only captured about 56.8% of in vitro confirmed off-target interactions, but also identified the right pharmacological targets for 14 compounds as one of the top scoring targets. In conclusion, the OTSA process demonstrates good predictive performance characteristics and represents an additional tool with utility during the lead optimization stage of the drug discovery process. Additionally, the computed physiochemical properties such as clogP (i.e., lipophilicity), molecular weight, pKa and logS (i.e., solubility) were found to be statistically different between the approved and discontinued drugs, but the internal compounds were close to the approved drugs space in most part. Frontiers Media S.A. 2019-07-17 /pmc/articles/PMC7931946/ /pubmed/33693348 http://dx.doi.org/10.3389/fdata.2019.00025 Text en Copyright © 2019 Rao, Gupta, Liguori, Hu, Huang, Mantena, Mittelstadt, Blomme and Van Vleet. http://creativecommons.org/licenses/by/4.0/ This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
spellingShingle Big Data
Rao, Mohan S.
Gupta, Rishi
Liguori, Michael J.
Hu, Mufeng
Huang, Xin
Mantena, Srinivasa R.
Mittelstadt, Scott W.
Blomme, Eric A. G.
Van Vleet, Terry R.
Novel Computational Approach to Predict Off-Target Interactions for Small Molecules
title Novel Computational Approach to Predict Off-Target Interactions for Small Molecules
title_full Novel Computational Approach to Predict Off-Target Interactions for Small Molecules
title_fullStr Novel Computational Approach to Predict Off-Target Interactions for Small Molecules
title_full_unstemmed Novel Computational Approach to Predict Off-Target Interactions for Small Molecules
title_short Novel Computational Approach to Predict Off-Target Interactions for Small Molecules
title_sort novel computational approach to predict off-target interactions for small molecules
topic Big Data
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7931946/
https://www.ncbi.nlm.nih.gov/pubmed/33693348
http://dx.doi.org/10.3389/fdata.2019.00025
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