Deep learning identifies genome-wide DNA binding sites of long noncoding RNAs.
Fan WangPranik ChainaniTommy WhiteJin YangYu LiuBenjamin SoibamPublished in: RNA biology (2018)
Long noncoding RNAs (lncRNAs) can exert their function by interacting with the DNA via triplex structure formation. Even though this has been validated with a handful of experiments, a genome-wide analysis of lncRNA-DNA binding is needed. In this paper, we develop and interpret deep learning models that predict the genome-wide binding sites deciphered by ChIRP-Seq experiments of 12 different lncRNAs. Among the several deep learning architectures tested, a simple architecture consisting of two convolutional neural network layers performed the best suggesting local sequence patterns as determinants of the interaction. Further interpretation of the kernels in the model revealed that these local sequence patterns form triplex structures with the corresponding lncRNAs. We uncovered several novel triplexes forming domains (TFDs) of these 12 lncRNAs and previously experimentally verified TFDs of lncRNAs HOTAIR and MEG3. We experimentally verified such two novel TFDs of lncRNAs HOTAIR and TUG1 predicted by our method (but previously unreported) using Electrophoretic mobility shift assays. In conclusion, we show that simple deep learning architecture can accurately predict genome-wide binding sites of lncRNAs and interpretation of the models suggest RNA:DNA:DNA triplex formation as a viable mechanism underlying lncRNA-DNA interactions at genome-wide level.
Keyphrases
- genome wide
- deep learning
- dna binding
- convolutional neural network
- dna methylation
- circulating tumor
- network analysis
- copy number
- artificial intelligence
- genome wide identification
- genome wide analysis
- cell free
- transcription factor
- single molecule
- machine learning
- nucleic acid
- gene expression
- long non coding rna
- high throughput
- single cell
- mass spectrometry
- long noncoding rna
- high resolution
- functional connectivity