Predicting synergism of cancer drug combinations using NCI-ALMANAC data

Sidorov, Pavel; Naulaerts, Stefan; Ariey-Bonnet, Jérémy; Pasquier, Eddy; Ballester, Pedro J.

doi:10.1101/504076

Cited by 29 publications

(35 citation statements)

References 96 publications

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“…Overall, a correlation between predictive power and feature importance was not observed be the cause of this behaviour. To further evaluate the practical utility of QAFFP, future studies will be needed to challenge them in more complex scenarios, including the modeling of the synergistic or antagonistic effect of compound combinations [79][80][81][82], and to test whether the integration of QAFFP and cell line profiling data sets (e.g., basal gene expression profiles, or changes in gene expression induced upon compound administration) improves drug sensitivity modeling.…”

Section: Discussionmentioning

confidence: 99%

QSAR-derived affinity fingerprints (part 2): modeling performance for potency prediction

et al. 2020

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Affinity fingerprints report the activity of small molecules across a set of assays, and thus permit to gather information about the bioactivities of structurally dissimilar compounds, where models based on chemical structure alone are often limited, and model complex biological endpoints, such as human toxicity and in vitro cancer cell line sensitivity. Here, we propose to model in vitro compound activity using computationally predicted bioactivity profiles as compound descriptors. To this aim, we apply and validate a framework for the calculation of QSAR-derived affinity fingerprints (QAFFP) using a set of 1360 QSAR models generated using K i , K d , IC 50 and EC 50 data from ChEMBL database. QAFFP thus represent a method to encode and relate compounds on the basis of their similarity in bioactivity space. To benchmark the predictive power of QAFFP we assembled IC 50 data from ChEMBL database for 18 diverse cancer cell lines widely used in preclinical drug discovery, and 25 diverse protein target data sets. This study complements part 1 where the performance of QAFFP in similarity searching, scaffold hopping, and bioactivity classification is evaluated. Despite being inherently noisy, we show that using QAFFP as descriptors leads to errors in prediction on the test set in the ~ 0.65-0.95 pIC 50 units range, which are comparable to the estimated uncertainty of bioactivity data in ChEMBL (0.76-1.00 pIC 50 units). We find that the predictive power of QAFFP is slightly worse than that of Morgan2 fingerprints and 1D and 2D physicochemical descriptors, with an effect size in the 0.02-0.08 pIC 50 units range. Including QSAR models with low predictive power in the generation of QAFFP does not lead to improved predictive power. Given that the QSAR models we used to compute the QAFFP were selected on the basis of data availability alone, we anticipate better modeling results for QAFFP generated using more diverse and biologically meaningful targets. Data sets and Python code are publicly available at https ://githu b.com/isidr oc/QAFFP _regre ssion .

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Section: Discussionmentioning

confidence: 99%

QSAR-derived affinity fingerprints (part 2): modeling performance for potency prediction

et al. 2020

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“…However, even such learning algorithms tend to overfit training data due to their model complexity [ 18 ]. An overfitted model predicts training data much better than test data, which we have observed when using learning algorithms such as RF [ 15 , 19 ] or XGBoost [ 20 , 21 ]. An attractive way to reduce model complexity is reducing the number of input features, but if such a reduction is too large, then it will cause model underfitting (i.e., the model not being sufficiently complex for the data).…”

Section: Introductionmentioning

confidence: 99%

Concise Polygenic Models for Cancer-Specific Identification of Drug-Sensitive Tumors from Their Multi-Omics Profiles

2020

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In silico models to predict which tumors will respond to a given drug are necessary for Precision Oncology. However, predictive models are only available for a handful of cases (each case being a given drug acting on tumors of a specific cancer type). A way to generate predictive models for the remaining cases is with suitable machine learning algorithms that are yet to be applied to existing in vitro pharmacogenomics datasets. Here, we apply XGBoost integrated with a stringent feature selection approach, which is an algorithm that is advantageous for these high-dimensional problems. Thus, we identified and validated 118 predictive models for 62 drugs across five cancer types by exploiting four molecular profiles (sequence mutations, copy-number alterations, gene expression, and DNA methylation). Predictive models were found in each cancer type and with every molecular profile. On average, no omics profile or cancer type obtained models with higher predictive accuracy than the rest. However, within a given cancer type, some molecular profiles were overrepresented among predictive models. For instance, CNA profiles were predictive in breast invasive carcinoma (BRCA) cell lines, but not in small cell lung cancer (SCLC) cell lines where gene expression (GEX) and DNA methylation profiles were the most predictive. Lastly, we identified the best XGBoost model per cancer type and analyzed their selected features. For each model, some of the genes in the selected list had already been found to be individually linked to the response to that drug, providing additional evidence of the usefulness of these models and the merits of the feature selection scheme.

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“…Computational approaches to model and predict the synergy of drug combinations include machine-learning methods (DeepSynergy [ 15 ]; random forest (RF); extreme gradient boosting (XGBoost) [ 16 ]; and graph convolutional network (GCN) [ 17 ]), network methods [ 18 , 19 ], and systems biology methods [ 10 , 20 , 21 ]. Though these computational biology models differ in their analytical and theoretical methods, they share similar feature sets, including drug and cell-line features.…”

Section: Introductionmentioning

confidence: 99%

Essentiality and Transcriptome-Enriched Pathway Scores Predict Drug-Combination Synergy

Huo

et al. 2020

Biology

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In the prediction of the synergy of drug combinations, systems pharmacology models expand the scope of experiment screening and overcome the limitations of current computational models posed by their lack of mechanical interpretation and integration of gene essentiality. We therefore investigated the synergy of drug combinations for cancer therapies utilizing records in NCI ALMANAC, and we employed logistic regression to test the statistical significance of gene and pathway features in that interaction. We trained our predictive models using 43 NCI-60 cell lines, 165 KEGG pathways, and 114 drug pairs. Scores of drug-combination synergies showed a stronger correlation with pathway than gene features in overall trend analysis and a significant association with both genes and pathways in genome-wide association analyses. However, we observed little overlap of significant gene expressions and essentialities and no significant evidence that associated target and non-target genes and their pathways. We were able to validate four drug-combination pathways between two drug combinations, Nelarabine-Exemestane and Docetaxel-Vermurafenib, and two signaling pathways, PI3K-AKT and AMPK, in 16 cell lines. In conclusion, pathways significantly outperformed genes in predicting drug-combination synergy, and because they have very different mechanisms, gene expression and essentiality should be considered in combination rather than individually to improve this prediction.

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Predicting synergism of cancer drug combinations using NCI-ALMANAC data

Cited by 29 publications

References 96 publications

QSAR-derived affinity fingerprints (part 2): modeling performance for potency prediction

QSAR-derived affinity fingerprints (part 2): modeling performance for potency prediction

Concise Polygenic Models for Cancer-Specific Identification of Drug-Sensitive Tumors from Their Multi-Omics Profiles

Essentiality and Transcriptome-Enriched Pathway Scores Predict Drug-Combination Synergy

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