Towards in silico CLIP-seq: predicting protein-RNA interaction via sequence-to-signal learning

Marc Horlacher; Nils Wagner; Lambert Moyon; Klara Kuret; Nicolas Goedert; Marco Salvatore; Jernej Ule; Julien Gagneur; Ole Winther; Annalisa Marsico

doi:10.1186/s13059-023-03015-7

Towards in silico CLIP-seq: predicting protein-RNA interaction via sequence-to-signal learning

Marc Horlacher
, Nils Wagner
, Lambert Moyon
, Klara Kuret
, Nicolas Goedert
, Marco Salvatore
, Jernej Ule
, Julien Gagneur
, Ole Winther
, Annalisa Marsico

Informatics 29 - Chair of Computational Molecular Medicine

Research output: Contribution to journal › Article › peer-review

17 Scopus citations

Abstract

We present RBPNet, a novel deep learning method, which predicts CLIP-seq crosslink count distribution from RNA sequence at single-nucleotide resolution. By training on up to a million regions, RBPNet achieves high generalization on eCLIP, iCLIP and miCLIP assays, outperforming state-of-the-art classifiers. RBPNet performs bias correction by modeling the raw signal as a mixture of the protein-specific and background signal. Through model interrogation via Integrated Gradients, RBPNet identifies predictive sub-sequences that correspond to known and novel binding motifs and enables variant-impact scoring via in silico mutagenesis. Together, RBPNet improves imputation of protein-RNA interactions, as well as mechanistic interpretation of predictions.

Original language	English
Article number	180
Journal	Genome Biology
Volume	24
Issue number	1
DOIs	https://doi.org/10.1186/s13059-023-03015-7
State	Published - Dec 2023

Keywords

CLIP-seq
Computational biology
Deep learning
Protein-RNA interaction

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10.1186/s13059-023-03015-7

Cite this

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title = "Towards in silico CLIP-seq: predicting protein-RNA interaction via sequence-to-signal learning",

abstract = "We present RBPNet, a novel deep learning method, which predicts CLIP-seq crosslink count distribution from RNA sequence at single-nucleotide resolution. By training on up to a million regions, RBPNet achieves high generalization on eCLIP, iCLIP and miCLIP assays, outperforming state-of-the-art classifiers. RBPNet performs bias correction by modeling the raw signal as a mixture of the protein-specific and background signal. Through model interrogation via Integrated Gradients, RBPNet identifies predictive sub-sequences that correspond to known and novel binding motifs and enables variant-impact scoring via in silico mutagenesis. Together, RBPNet improves imputation of protein-RNA interactions, as well as mechanistic interpretation of predictions.",

keywords = "CLIP-seq, Computational biology, Deep learning, Protein-RNA interaction",

author = "Marc Horlacher and Nils Wagner and Lambert Moyon and Klara Kuret and Nicolas Goedert and Marco Salvatore and Jernej Ule and Julien Gagneur and Ole Winther and Annalisa Marsico",

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T2 - predicting protein-RNA interaction via sequence-to-signal learning

AU - Horlacher, Marc

AU - Wagner, Nils

AU - Moyon, Lambert

AU - Kuret, Klara

AU - Goedert, Nicolas

AU - Salvatore, Marco

AU - Ule, Jernej

AU - Gagneur, Julien

AU - Winther, Ole

AU - Marsico, Annalisa

PY - 2023/12

Y1 - 2023/12

N2 - We present RBPNet, a novel deep learning method, which predicts CLIP-seq crosslink count distribution from RNA sequence at single-nucleotide resolution. By training on up to a million regions, RBPNet achieves high generalization on eCLIP, iCLIP and miCLIP assays, outperforming state-of-the-art classifiers. RBPNet performs bias correction by modeling the raw signal as a mixture of the protein-specific and background signal. Through model interrogation via Integrated Gradients, RBPNet identifies predictive sub-sequences that correspond to known and novel binding motifs and enables variant-impact scoring via in silico mutagenesis. Together, RBPNet improves imputation of protein-RNA interactions, as well as mechanistic interpretation of predictions.

AB - We present RBPNet, a novel deep learning method, which predicts CLIP-seq crosslink count distribution from RNA sequence at single-nucleotide resolution. By training on up to a million regions, RBPNet achieves high generalization on eCLIP, iCLIP and miCLIP assays, outperforming state-of-the-art classifiers. RBPNet performs bias correction by modeling the raw signal as a mixture of the protein-specific and background signal. Through model interrogation via Integrated Gradients, RBPNet identifies predictive sub-sequences that correspond to known and novel binding motifs and enables variant-impact scoring via in silico mutagenesis. Together, RBPNet improves imputation of protein-RNA interactions, as well as mechanistic interpretation of predictions.

KW - CLIP-seq

KW - Computational biology

KW - Deep learning

KW - Protein-RNA interaction

UR - https://www.scopus.com/pages/publications/85166598318

U2 - 10.1186/s13059-023-03015-7

DO - 10.1186/s13059-023-03015-7

M3 - Article

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SN - 1474-7596

VL - 24

JO - Genome Biology

JF - Genome Biology

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ER -

Towards in silico CLIP-seq: predicting protein-RNA interaction via sequence-to-signal learning

Abstract

Keywords

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