miRNAs are involved in many critical cellular activities through binding to their mRNA targets, e.g. in cell proliferation, differentiation, death, growth control, and developmental timing. Accurate prediction of miRNA targets can assist efficient experimental investigations on the functional roles of miRNAs. Their prediction, however, remains a challengeable task due to the lack of experimental data about the tertiary structure of miRNA-target binding duplexes. In particular, correlations of nucleotides in the binding duplexes may not be limited to the canonical Watson Crick base pairs (BPs) as they have been perceived; methods based on secondary structure prediction (typically minimum free energy (MFE)) have only had mix success. In this work, we characterized miRNA binding duplexes with a graph model to capture the correlations between pairs of nucleotides of an miRNA and its target sequences. We developed machine learning algorithms to train the graph model to predict the target sites of miRNAs. In particular, because imbalance between positive and negative samples can significantly deteriorate the performance of machine learning methods, we designed a novel method to re-sample available dataset to produce more informative data learning process.

We evaluated our model and miRNA target prediction method on human miRNAs and target data obtained from mirTarBase, a database of experimentally verified miRNA-target interactions. The performance of our method in target prediction achieved a sensitivity of 86% with a false positive rate below 13%. In comparison with the state-of-the-art methods miRanda and RNAhybrid on the test data, our method outperforms both of them by a significant margin.

The source codes, test sets and model files all are available at http://rna-informatics.uga.edu/?f=software&p=GraB-miTarget.

Keywords:

References

1. Liu B, Fang L, Liu F, Wang X, Chen J, Chou K-C , Identification of real microrna precursors with a pseudo structure status composition approach, PloS one 10 (3) :e0121501, 2015. Crossref, Medline, Google Scholar
2. Huang Y, Shen XJ, Zou Q, Wang SP, Tang SM, Zhang GZ , Biological functions of micrornas: A review, J Physiol Bioch 67 (1) :129–139, 2011. Crossref, Medline, Google Scholar
3. Ameres SL, Zamore PD , Diversifying microrna sequence and function, Nat Rev Mol Cell Biol 14 (8) :475–488, 2013. Crossref, Medline, Google Scholar
4. Krol J, Loedige I, Filipowicz W , The widespread regulation of microrna biogenesis, function and decay, Nat Rev Genet 11 (9) :597–610, 2010. Crossref, Medline, Google Scholar
5. Fabian MR, Sonenberg N , The mechanics of mirna-mediated gene silencing: A look under the hood of mirisc, Nat Struct Mol Biol 19 (6) :586–593, 2012. Crossref, Medline, Google Scholar
6. Sturm M, Hackenberg M, Langenberger D, Frishman D , Targetspy: A supervised machine learning approach for microrna target prediction, BMC Bioinformatics 11 (1) :1, 2010. Crossref, Medline, Google Scholar
7. Yue D, Liu H, Huang Y , Survey of computational algorithms for microrna target prediction, Curr. Genom 10 (7) :478–492, 2009. Crossref, Medline, Google Scholar
8. Agarwal V, Bell GW, Nam J-W, Bartel DP , Predicting effective microrna target sites in mammalian mrnas, Elife 4 :e05005, 2015. Crossref, Google Scholar
9. Betel D, Wilson M, Gabow A, Marks DS, Sander C , The microrna. org resource: Targets and expression, Nucleic Acids Res 36 (Suppl_1) :D149–D153, 2008. Medline, Google Scholar
10. Maragkakis M, Reczko M, Simossis VA, Alexiou P, Papadopoulos GL, Dalamagas T, Giannopoulos G, Goumas G, Koukis E, Kourtis K et al., Diana-microt web server: Elucidating microrna functions through target prediction, Nucleic Acids Res 37 (Suppl_2) :W273–W276, 2009. Crossref, Medline, Google Scholar
11. Rehmsmeier M, Steffen P, Höchsmann M, Giegerich R , Fast and Effective Prediction of microRNA/Target Duplexes, Vol. 10, Cold Spring Harbor Lab, 2004. Crossref, Google Scholar
12. Kim S-K, Nam J-W, Rhee J-K, Lee W-J, Zhang B-T , Mitarget: Microrna target gene prediction using a support vector machine, BMC Bioinformatics 7 (1) :411, 2006. Crossref, Medline, Google Scholar
13. Kertesz M, Iovino N, Unnerstall U, Gaul U, Segal E , The role of site accessibility in microrna target recognition, Nat Genet 39 (10) :1278–1284, 2007. Crossref, Medline, Google Scholar
14. Betel D, Koppal A, Agius P, Sander C, Leslie C , Comprehensive modeling of microrna targets predicts functional non-conserved and non-canonical sites, Genome Biol 11 (8) :R90, 2010. Crossref, Medline, Google Scholar
15. Ghoshal A, Grama A, Bagchi S, Chaterji S , An ensemble svm model for the accurate prediction of non-canonical microrna targets, Proc 6th ACM Conf Bioinformatics, Computational Biology and Health Informatics, pp. 403–412, 2015. Google Scholar
16. Hsu S-D, Tseng Y-T, Shrestha S, Lin Y-L, Khaleel A, Chou C-H, Chu C-F, Huang H-Y, Lin C-M, Ho S-Y , et al., Mirtarbase update 2014: An information resource for experimentally validated mirna-target interactions, Nucleic Acids Res 42 (D1) :D78–D85, 2014. Crossref, Medline, Google Scholar
17. Gruber AR, Lorenz R, Bernhart SH, Neuböck R, Hofacker IL , The vienna rna websuite, Nucleic Acids Research 36 (Suppl_2) :W70–W74, 2008. Crossref, Medline, Google Scholar
18. Schirle NT, Sheu-Gruttadauria J, MacRae IJ , Structural basis for microrna targeting, Science 346 (6209) :608–613, 2014. Crossref, Medline, Google Scholar
19. Loeb GB, Khan AA, Canner D, Hiatt JB, Shendure J, Darnell RB, Leslie CS, Rudensky AY , Transcriptome-wide mir-155 binding map reveals widespread noncanonical microrna targeting, Mol Cell 48 (5) :760–770, 2012. Crossref, Medline, Google Scholar
20. Peterson SM, Thompson JA, Ufkin ML, Sathyanarayana P, Liaw L, Congdon CB , Common features of microrna target prediction tools, Front Genet 5 :23, 2014. Crossref, Medline, Google Scholar
21. Ellwanger DC, Büttner FA, Mewes H-W, Stümpflen V , The sufficient minimal set of mirna seed types, Bioinformatics 27 (10) :1346–1350, 2011. Crossref, Medline, Google Scholar
22. Aggarwal CC, Reddy CK , Data Clustering: Algorithms and Applications, CRC Press, 2013. Crossref, Google Scholar
23. Aggarwal CC, Hinneburg A, Keim DA , On the surprising behavior of distance metrics in high dimensional space. In International Conference on Database Theory (Springer, 2001), pp. 420–434. Crossref, Google Scholar
24. Chang C-C, Lin C-J , Libsvm: A library for support vector machines, ACM Trans Intell Syst Technol 2 (3) :27, 2011. Crossref, Google Scholar
25. Bergstra J, Bengio Y , Random search for hyper-parameter optimization, J Mach Learn Res 13 :281–305, 2012. Google Scholar
26. Krüger J, Rehmsmeier M , Rnahybrid: microrna target prediction easy, fast and flexible, Nucleic Acids Res, 34 (Suppl_2) :W451–W454, 2006. Crossref, Medline, Google Scholar
27. Wang X , mirdb: A microrna target prediction and functional annotation database with a wiki interface, Rna, 14 (6) :1012–1017, 2008. Crossref, Medline, Google Scholar
28. Ding J, Li X, Hu H , Tarpmir: A new approach for microrna target site prediction, Bioinformatics, 32 (18) :2768–2775, 2016. Crossref, Medline, Google Scholar
29. Griffiths-Jones S, Grocock RJ, Van Dongen S, Bateman A, Enright AJ , mirbase: Microrna sequences, targets and gene nomenclature, Nucleic Acids Res 34 (Suppl_1) :D140–D144, 2006. Crossref, Medline, Google Scholar
30. Kim S-K, Nam J-W, Rhee J-K, Lee W-J, Zhang B-T , mitarget: Microrna target gene prediction using a support vector machine, BMC Bioinformatics 7 (1) :411, 2006. Crossref, Medline, Google Scholar
31. Dweep H, Sticht C, Pandey P, Gretz N , mirwalk–database: Prediction of possible mirna binding sites by walking the genes of three genomes, J. Biomed Inf 44 (5) :839–847, 2011. Crossref, Medline, Google Scholar
32. Betel D, Koppal A, Agius P, Sander C, Leslie C , Comprehensive modeling of microrna targets predicts functional non-conserved and non-canonical sites, Genome Biol 11 (8) :R90, 2010. Crossref, Medline, Google Scholar
33. Maziere P, Enright AJ , Prediction of microrna targets, Drug Discov Today 12 (11–12) :452–458, 2007. Crossref, Medline, Google Scholar