Supervised prediction of drug-induced nephrotoxicity based on interleukin-6 and -8 expression levels

BackgroundDrug-induced nephrotoxicity causes acute kidney injury and chronic kidney diseases, and is a major reason for late-stage failures in the clinical trials of new drugs. Therefore, early, pre-clinical prediction of nephrotoxicity could help to prioritize drug candidates for further evaluations, and increase the success rates of clinical trials. Recently, an in vitro model for predicting renal-proximal-tubular-cell (PTC) toxicity based on the expression levels of two inflammatory markers, interleukin (IL)-6 and -8, has been described. However, this and other existing models usually use linear and manually determined thresholds to predict nephrotoxicity. Automated machine learning algorithms may improve these models, and produce more accurate and unbiased predictions.ResultsHere, we report a systematic comparison of the performances of four supervised classifiers, namely random forest, support vector machine, k-nearest-neighbor and naive Bayes classifiers, in predicting PTC toxicity based on IL-6 and -8 expression levels. Using a dataset of human primary PTCs treated with 41 well-characterized compounds that are toxic or not toxic to PTC, we found that random forest classifiers have the highest cross-validated classification performance (mean balanced accuracy = 87.8%, sensitivity = 89.4%, and specificity = 85.9%). Furthermore, we also found that IL-8 is more predictive than IL-6, but a combination of both markers gives higher classification accuracy. Finally, we also show that random forest classifiers trained automatically on the whole dataset have higher mean balanced accuracy than a previous threshold-based classifier constructed for the same dataset (99.3% vs. 80.7%).ConclusionsOur results suggest that a random forest classifier can be used to automatically predict drug-induced PTC toxicity based on the expression levels of IL-6 and -8.

[1]  D. Choudhury,et al.  Drug-associated renal dysfunction and injury , 2006, Nature Clinical Practice Nephrology.

[2]  Corinna Cortes,et al.  Support-Vector Networks , 1995, Machine Learning.

[3]  Hae-Chang Rim,et al.  Some Effective Techniques for Naive Bayes Text Classification , 2006, IEEE Transactions on Knowledge and Data Engineering.

[4]  G. Willsky,et al.  Renal drug metabolism. , 1998, Pharmacological reviews.

[5]  C. Viscoli,et al.  The effect of acute renal failure on mortality. A cohort analysis. , 1996, JAMA.

[6]  Leena Lepistö,et al.  Rock image classification based on k-nearest neighbour voting , 2006 .

[7]  Thomas J. Watson,et al.  An empirical study of the naive Bayes classifier , 2001 .

[8]  D. Zink,et al.  An in vitro method for the prediction of renal proximal tubular toxicity in humans , 2013 .

[9]  Douglas Ferguson,et al.  Early prediction of polymyxin-induced nephrotoxicity with next-generation urinary kidney injury biomarkers. , 2014, Toxicological sciences : an official journal of the Society of Toxicology.

[10]  A. Novick,et al.  Expression of IL-8 during Reperfusion of Renal Allografts Is Dependent on Ischemic Time , 2006, Transplantation.

[11]  D. Tramma,et al.  Interleukin-6 and interleukin-8 levels in the urine of children with renal scarring , 2012, Pediatric Nephrology.

[12]  W. Waring,et al.  Earlier recognition of nephrotoxicity using novel biomarkers of acute kidney injury , 2011, Clinical toxicology.

[13]  BMC Bioinformatics , 2005 .

[14]  Peng Huang,et al.  Drug-induced nephrotoxicity: clinical impact and preclinical in vitro models. , 2014, Molecular pharmaceutics.

[15]  Joseph V Bonventre,et al.  Next-generation biomarkers for detecting kidney toxicity , 2010, Nature Biotechnology.

[16]  Gunnar Rätsch,et al.  An introduction to kernel-based learning algorithms , 2001, IEEE Trans. Neural Networks.

[17]  Tom Fawcett,et al.  An introduction to ROC analysis , 2006, Pattern Recognit. Lett..

[18]  Z. Endre,et al.  Renal biomarkers predict nephrotoxicity after paraquat. , 2013, Toxicology letters.

[19]  Jieping Ye,et al.  SVM versus Least Squares SVM , 2007, AISTATS.

[20]  Chih-Jen Lin,et al.  A Practical Guide to Support Vector Classication , 2008 .

[21]  C. Cheadle,et al.  The local and systemic inflammatory transcriptome after acute kidney injury. , 2008, Journal of the American Society of Nephrology : JASN.

[22]  Leo Breiman,et al.  Random Forests , 2001, Machine Learning.

[23]  Halil Yigit,et al.  A weighting approach for KNN classifier , 2013, 2013 International Conference on Electronics, Computer and Computation (ICECCO).

[24]  C. Edelstein,et al.  Mediators of Inflammation in Acute Kidney Injury , 2010, Mediators of inflammation.

[25]  D. Zink,et al.  Identification of nephrotoxic compounds with embryonic stem-cell-derived human renal proximal tubular-like cells. , 2014, Molecular pharmaceutics.

[26]  Robert Tibshirani,et al.  The Elements of Statistical Learning: Data Mining, Inference, and Prediction, 2nd Edition , 2001, Springer Series in Statistics.

[27]  M. Perazella,et al.  Renal vulnerability to drug toxicity. , 2009, Clinical journal of the American Society of Nephrology : CJASN.

[28]  C. Nzerue,et al.  How to prevent, recognize, and treat drug-induced nephrotoxicity. , 2002, Cleveland Clinic journal of medicine.

[29]  Cynthia A Afshari,et al.  Prediction of Nephrotoxicant Action and Identification of Candidate Toxicity-Related Biomarkers , 2005, Toxicologic pathology.

[30]  Constantin F. Aliferis,et al.  A comprehensive comparison of random forests and support vector machines for microarray-based cancer classification , 2008, BMC Bioinformatics.

[31]  水谷 博之,et al.  SVM (Support Vector Machine) , 1999 .