Genetic Interactions and Tissue Specificity Modulate the Association of Mutations with Drug Response.
Dina CramerJohanna MazurOctavio EspinosaMatthias SchlesnerDaniel HübschmannRoland EilsEike StaubPublished in: Molecular cancer therapeutics (2019)
In oncology, biomarkers are widely used to predict subgroups of patients that respond to a given drug. Although clinical decisions often rely on single gene biomarkers, machine learning approaches tend to generate complex multi-gene biomarkers that are hard to interpret. Models predicting drug response based on multiple altered genes often assume that the effects of single alterations are independent. We asked whether the association of cancer driver mutations with drug response is modulated by other driver mutations or the tissue of origin. We developed an analytic framework based on linear regression to study interactions in pharmacogenomic data from two large cancer cell line panels. Starting from a model with only covariates, we included additional variables only if they significantly improved simpler models. This allows to systematically assess interactions in small, easily interpretable models. Our results show that including mutation-mutation interactions in drug response prediction models tends to improve model performance and robustness. For example, we found that TP53 mutations decrease sensitivity to BRAF inhibitors in BRAF-mutated cell lines and patient tumors, suggesting a therapeutic benefit of combining inhibition of oncogenic BRAF with reactivation of the tumor suppressor TP53. Moreover, we identified tissue-specific mutation-drug associations and synthetic lethal triplets where the simultaneous mutation of two genes sensitizes cells to a drug. In summary, our interaction-based approach contributes to a holistic view on the determining factors of drug response.
Keyphrases
- machine learning
- genome wide
- adverse drug
- end stage renal disease
- drug induced
- induced apoptosis
- squamous cell carcinoma
- newly diagnosed
- copy number
- papillary thyroid
- young adults
- chronic kidney disease
- emergency department
- ejection fraction
- cell proliferation
- case report
- signaling pathway
- prognostic factors
- endoplasmic reticulum stress
- oxidative stress
- clinical decision support
- wild type
- childhood cancer