Effective gene expression prediction from sequence by integrating long-range interactions
| Autor: | Agnieszka Grabska-Barwinska, Kyle R. Taylor, Žiga Avsec, Pushmeet Kohli, Daniel Visentin, John M. Jumper, David R. Kelley, Joseph R. Ledsam, Vikram Agarwal, Yannis M. Assael |
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| Rok vydání: | 2021 |
| Předmět: |
Computer science
Cell Biology Computational biology Biochemistry Noncoding DNA Genome Article Human genetics DNA sequencing Gene expression Machine learning 1000 Genomes Project Saturated mutagenesis Transcriptomics Enhancer Molecular Biology Massively parallel Gene Software Biotechnology Sequence (medicine) |
| Zdroj: | Nature Methods |
| DOI: | 10.1101/2021.04.07.438649 |
| Popis: | How noncoding DNA determines gene expression in different cell types is a major unsolved problem, and critical downstream applications in human genetics depend on improved solutions. Here, we report substantially improved gene expression prediction accuracy from DNA sequences through the use of a deep learning architecture, called Enformer, that is able to integrate information from long-range interactions (up to 100 kb away) in the genome. This improvement yielded more accurate variant effect predictions on gene expression for both natural genetic variants and saturation mutagenesis measured by massively parallel reporter assays. Furthermore, Enformer learned to predict enhancer–promoter interactions directly from the DNA sequence competitively with methods that take direct experimental data as input. We expect that these advances will enable more effective fine-mapping of human disease associations and provide a framework to interpret cis-regulatory evolution. By using a new deep learning architecture, Enformer leverages long-range information to improve prediction of gene expression on the basis of DNA sequence. |
| Databáze: | OpenAIRE |
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