<p>Deep learning models that predict functional genomic measurements from DNA sequences are powerful tools for deciphering the genetic regulatory code. Existing methods involve a trade-off between input sequence length and prediction resolution, thereby limiting their modality scope and performance<sup><CitationRef AdditionalCitationIDS="CR2 CR3 CR4" CitationID="CR1">1</CitationRef>–<CitationRef CitationID="CR5">5</CitationRef></sup>. We present AlphaGenome, a unified DNA sequence model, which takes as input 1 Mb of DNA sequence and predicts thousands of functional genomic tracks up to single-base-pair resolution across diverse modalities. The modalities include gene expression, transcription initiation, chromatin accessibility, histone modifications, transcription factor binding, chromatin contact maps, splice site usage and splice junction coordinates and strength. Trained on human and mouse genomes, AlphaGenome matches or exceeds the strongest available external models in 25 of 26 evaluations of variant effect prediction. The ability of AlphaGenome to simultaneously score variant effects across all modalities accurately recapitulates the mechanisms of clinically relevant variants near the <i>TAL1</i> oncogene<sup><CitationRef CitationID="CR6">6</CitationRef></sup>. To facilitate broader use, we provide tools for making genome track and variant effect predictions from sequence.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Advancing regulatory variant effect prediction with AlphaGenome

  • Žiga Avsec,
  • Natasha Latysheva,
  • Jun Cheng,
  • Guido Novati,
  • Kyle R. Taylor,
  • Tom Ward,
  • Clare Bycroft,
  • Lauren Nicolaisen,
  • Eirini Arvaniti,
  • Joshua Pan,
  • Raina Thomas,
  • Vincent Dutordoir,
  • Matteo Perino,
  • Soham De,
  • Alexander Karollus,
  • Adam Gayoso,
  • Toby Sargeant,
  • Anne Mottram,
  • Lai Hong Wong,
  • Pavol Drotár,
  • Adam Kosiorek,
  • Andrew Senior,
  • Richard Tanburn,
  • Taylor Applebaum,
  • Souradeep Basu,
  • Demis Hassabis,
  • Pushmeet Kohli

摘要

Deep learning models that predict functional genomic measurements from DNA sequences are powerful tools for deciphering the genetic regulatory code. Existing methods involve a trade-off between input sequence length and prediction resolution, thereby limiting their modality scope and performance15. We present AlphaGenome, a unified DNA sequence model, which takes as input 1 Mb of DNA sequence and predicts thousands of functional genomic tracks up to single-base-pair resolution across diverse modalities. The modalities include gene expression, transcription initiation, chromatin accessibility, histone modifications, transcription factor binding, chromatin contact maps, splice site usage and splice junction coordinates and strength. Trained on human and mouse genomes, AlphaGenome matches or exceeds the strongest available external models in 25 of 26 evaluations of variant effect prediction. The ability of AlphaGenome to simultaneously score variant effects across all modalities accurately recapitulates the mechanisms of clinically relevant variants near the TAL1 oncogene6. To facilitate broader use, we provide tools for making genome track and variant effect predictions from sequence.