MMSplice: Modular modeling improves the predictions of genetic variant effects on splicing

Jun Cheng; Thi Yen Duong Nguyen; Kamil J. Cygan; Muhammed Hasan Çelik; William G. Fairbrother; Žiga Avsec; Julien Gagneur

doi:10.1186/s13059-019-1653-z

MMSplice: Modular modeling improves the predictions of genetic variant effects on splicing

Jun Cheng
, Thi Yen Duong Nguyen
, Kamil J. Cygan
, Muhammed Hasan Çelik
, William G. Fairbrother
, Žiga Avsec
, Julien Gagneur

Informatics 29 - Chair of Computational Molecular Medicine

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

169 Scopus citations

Abstract

Predicting the effects of genetic variants on splicing is highly relevant for human genetics. We describe the framework MMSplice (modular modeling of splicing) with which we built the winning model of the CAGI5 exon skipping prediction challenge. The MMSplice modules are neural networks scoring exon, intron, and splice sites, trained on distinct large-scale genomics datasets. These modules are combined to predict effects of variants on exon skipping, splice site choice, splicing efficiency, and pathogenicity, with matched or higher performance than state-of-the-art. Our models, available in the repository Kipoi, apply to variants including indels directly from VCF files.

Original language	English
Article number	48
Journal	Genome Biology
Volume	20
Issue number	1
DOIs	https://doi.org/10.1186/s13059-019-1653-z
State	Published - 1 Mar 2019

Keywords

Deep learning
Modular modeling
Splicing
Variant effect
Variant pathogenicity

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10.1186/s13059-019-1653-z

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title = "MMSplice: Modular modeling improves the predictions of genetic variant effects on splicing",

abstract = "Predicting the effects of genetic variants on splicing is highly relevant for human genetics. We describe the framework MMSplice (modular modeling of splicing) with which we built the winning model of the CAGI5 exon skipping prediction challenge. The MMSplice modules are neural networks scoring exon, intron, and splice sites, trained on distinct large-scale genomics datasets. These modules are combined to predict effects of variants on exon skipping, splice site choice, splicing efficiency, and pathogenicity, with matched or higher performance than state-of-the-art. Our models, available in the repository Kipoi, apply to variants including indels directly from VCF files.",

keywords = "Deep learning, Modular modeling, Splicing, Variant effect, Variant pathogenicity",

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doi = "10.1186/s13059-019-1653-z",

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T2 - Modular modeling improves the predictions of genetic variant effects on splicing

AU - Cheng, Jun

AU - Nguyen, Thi Yen Duong

AU - Cygan, Kamil J.

AU - Çelik, Muhammed Hasan

AU - Fairbrother, William G.

AU - Avsec, Žiga

AU - Gagneur, Julien

PY - 2019/3/1

Y1 - 2019/3/1

N2 - Predicting the effects of genetic variants on splicing is highly relevant for human genetics. We describe the framework MMSplice (modular modeling of splicing) with which we built the winning model of the CAGI5 exon skipping prediction challenge. The MMSplice modules are neural networks scoring exon, intron, and splice sites, trained on distinct large-scale genomics datasets. These modules are combined to predict effects of variants on exon skipping, splice site choice, splicing efficiency, and pathogenicity, with matched or higher performance than state-of-the-art. Our models, available in the repository Kipoi, apply to variants including indels directly from VCF files.

AB - Predicting the effects of genetic variants on splicing is highly relevant for human genetics. We describe the framework MMSplice (modular modeling of splicing) with which we built the winning model of the CAGI5 exon skipping prediction challenge. The MMSplice modules are neural networks scoring exon, intron, and splice sites, trained on distinct large-scale genomics datasets. These modules are combined to predict effects of variants on exon skipping, splice site choice, splicing efficiency, and pathogenicity, with matched or higher performance than state-of-the-art. Our models, available in the repository Kipoi, apply to variants including indels directly from VCF files.

KW - Deep learning

KW - Modular modeling

KW - Splicing

KW - Variant effect

KW - Variant pathogenicity

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DO - 10.1186/s13059-019-1653-z

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SN - 1474-7596

VL - 20

JO - Genome Biology

JF - Genome Biology

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ER -

MMSplice: Modular modeling improves the predictions of genetic variant effects on splicing

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Keywords

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