Modeling Reactivity to Biological Macromolecules with a Deep Multitask Network

Hughes, Tyler B.; Dang, Na Le; Miller, Grover P.; Swamidass, S. Joshua

doi:10.1021/acscentsci.6b00162

Cited by 84 publications

(140 citation statements)

References 70 publications

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“…Our previous studies with the AMD have observed comparable drops in site-level (equivalent to the pair-level in this study) to molecule-level accuracy. 41,44,45 …”

Section: Resultsmentioning

confidence: 99%

“…83 Consequently, in future work we plan to incorporate the quinone formation model with already-developed reactivity models. 44,45 …”

Section: Model Limitationsmentioning

confidence: 99%

“…Within these quinone-forming molecules, the average pair AUC metric quantifies how frequently QP were ranked higher than other atom pairs. 41,44,45 Bottom left, the top-two metric was calculated, which counts a molecule correctly predicted if any of its QP received the first- or second-highest prediction. 32,34,41,52,53 By both metrics, the cross-validated pair-level scores outperformed atom quinone formation scores (AQS), computed by a control model that did not include training on the pair-level, instead mapping the atom-level to the pair-level by multiplying the scores of both atoms together.…”

Section: Figurementioning

confidence: 99%

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Deep Learning to Predict the Formation of Quinone Species in Drug Metabolism

Hughes

Swamidass

2017

Chem. Res. Toxicol.

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Many adverse drug reactions are thought to be caused by electrophilically reactive drug metabolites that conjugate to nucleophilic sites within DNA and proteins, causing cancer or toxic immune responses. Quinone species, including quinone-imines, quinone-methides, and imine-methides, are electrophilic Michael acceptors that are often highly reactive and comprise over 40% of all known reactive metabolites. Quinone metabolites are created by cytochromes P450 and peroxidases. For example, cytochromes P450 oxidize acetaminophen to N-acetyl-p-benzoquinone imine, which is electrophilically reactive and covalently binds to nucleophilic sites within proteins. This reactive quinone metabolite elicits a toxic immune response when acetaminophen exceeds a safe dose. Using a deep learning approach, this study reports the first published method for predicting quinone formation: the formation of a quinone species by metabolic oxidation. We model both one- and two-step quinone formation, enabling accurate quinone formation predictions in nonobvious cases. We predict atom pairs that form quinones with an AUC accuracy of 97.6%, and we identify molecules that form quinones with 88.2% AUC. By modeling the formation of quinones, one of the most common types of reactive metabolites, our method provides a rapid screening tool for a key drug toxicity risk. The XenoSite quinone formation model is available at http://swami.wustl.edu/xenosite/p/quinone.

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“…Our previous studies with the AMD have observed comparable drops in site-level (equivalent to the pair-level in this study) to molecule-level accuracy. 41,44,45 …”

Section: Resultsmentioning

confidence: 99%

“…83 Consequently, in future work we plan to incorporate the quinone formation model with already-developed reactivity models. 44,45 …”

Section: Model Limitationsmentioning

confidence: 99%

Section: Figurementioning

confidence: 99%

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Deep Learning to Predict the Formation of Quinone Species in Drug Metabolism

Hughes

Swamidass

2017

Chem. Res. Toxicol.

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“…Yoon et al [101] demonstrated that predicting the primary cancer site from cancer pathology reports together with its laterality substantially improved the performance for the latter task, indicating that multi-task learning can effectively leverage the commonality between two tasks using a shared representation. Many studies employed multi-task learning to predict chemical bioactivity [387,391] and drug toxicity [392,541]. Kearnes et al [385] systematically compared single-task and multi-task models for ADMET properties and found that multi-task learning generally improved performance.…”

Section: Multimodal Multi-task and Transfer Learningmentioning

confidence: 99%

Opportunities and obstacles for deep learning in biology and medicine

Ching

Himmelstein

Beaulieu‐Jones

et al. 2017

Preprint

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236

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Deep learning, which describes a class of machine learning algorithms, has recently showed impressive results across a variety of domains. Biology and medicine are data rich, but the data are complex and often ill-understood. Problems of this nature may be particularly well-suited to deep learning techniques. We examine applications of deep learning to a variety of biomedical problems—patient classification, fundamental biological processes, and treatment of patients—and discuss whether deep learning will transform these tasks or if the biomedical sphere poses unique challenges. We find that deep learning has yet to revolutionize or definitively resolve any of these problems, but promising advances have been made on the prior state of the art. Even when improvement over a previous baseline has been modest, we have seen signs that deep learning methods may speed or aid human investigation. More work is needed to address concerns related to interpretability and how to best model each problem. Furthermore, the limited amount of labeled data for training presents problems in some domains, as do legal and privacy constraints on work with sensitive health records. Nonetheless, we foresee deep learning powering changes at both bench and bedside with the potential to transform several areas of biology and medicine.

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“…Known sites of metabolism are marked with white circles. The metabolism and reactivity 91 predictions are plotted against each atom in the molecule, with color shading ranging from red (1.0, likely) to white (0.0, unlikely). Structural alerts indiscriminately flag both bioactivated and not-bioactivated compounds as problematic.…”

Section: Figurementioning

confidence: 99%

Computational Approach to Structural Alerts: Furans, Phenols, Nitroaromatics, and Thiophenes

Dang

Hughes

Miller

et al. 2017

Chem. Res. Toxicol.

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Structural alerts are commonly used in drug discovery to identify molecules likely to form reactive metabolites and thereby become toxic. Unfortunately, as useful as structural alerts are, they do not effectively model if, when, and why metabolism renders safe molecules toxic. Toxicity due to a specific structural alert is highly conditional, depending on the metabolism of the alert, the reactivity of its metabolites, dosage, and competing detoxification pathways. A systems approach, which explicitly models these pathways, could more effectively assess the toxicity risk of drug candidates. In this study, we demonstrated that mathematical models of P450 metabolism can predict the context-specific probability that a structural alert will be bioactivated in a given molecule. This study focuses on the furan, phenol, nitroaromatic, and thiophene alerts. Each of these structural alerts can produce reactive metabolites through certain metabolic pathways but not always. We tested whether our metabolism modeling approach, XenoSite, can predict when a given molecule’s alerts will be bioactivated. Specifically, we used models of epoxidation, quinone formation, reduction, and sulfur-oxidation to predict the bioactivation of furan-, phenol-, nitroaromatic-, and thiophene-containing drugs. Our models separated bioactivated and not-bioactivated furan-, phenol-, nitroaromatic-, and thiophene-containing drugs with AUC performances of 100%, 73%, 93%, and 88%, respectively. Metabolism models accurately predict whether alerts are bioactivated and thus serve as a practical approach to improve the interpretability and usefulness of structural alerts. We expect that this same computational approach can be extended to most other structural alerts and later integrated into toxicity risk models. This advance is one necessary step toward our long-term goal of building comprehensive metabolic models of bioactivation and detoxification to guide assessment and design of new therapeutic molecules.

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Modeling Reactivity to Biological Macromolecules with a Deep Multitask Network

Cited by 84 publications

References 70 publications

Deep Learning to Predict the Formation of Quinone Species in Drug Metabolism

Deep Learning to Predict the Formation of Quinone Species in Drug Metabolism

Opportunities and obstacles for deep learning in biology and medicine

Computational Approach to Structural Alerts: Furans, Phenols, Nitroaromatics, and Thiophenes

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