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Current genomic deep learning models display decreased performance in cell type-specific accessible regions.

Pooja Kathail1, Richard W Shuai2, Ryan Chung3

  • 1Center for Computational Biology, University of California, Berkeley, Berkeley, CA, USA. pooja.kathail@berkeley.edu.

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|August 1, 2024
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Genomic deep learning models show reduced accuracy in cell type-specific regulatory regions. Enhancing model capacity improves performance in these critical areas, offering new strategies for disease heritability studies.

Keywords:
Chromatin accessibilityDeep learningVariant effect prediction

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Area of Science:

  • Genomics
  • Computational Biology
  • Epigenetics

Background:

  • Deep learning models predict epigenetic features from DNA sequence.
  • Cis-regulatory elements (CREs) are crucial for gene regulation but form a small genomic fraction.
  • Cell type-specific CREs harbor significant complex disease heritability.

Purpose of the Study:

  • Evaluate genomic deep learning models in chromatin accessibility regions.
  • Compare general-purpose vs. tissue/task-specific models.
  • Identify strategies to improve model performance in cell type-specific regions.

Main Methods:

  • Assessed deep learning model performance across varying cell type specificity in accessible regions.
  • Compared general-purpose models (Enformer, Sei) with tailored models.
  • Investigated impact of model capacity and training strategies on performance.

Main Results:

  • Model accuracy varies genome-wide, decreasing in cell type-specific accessible regions.
  • Increased model capacity (single-task or high-capacity multi-task) improves performance in these regions.
  • Reference sequence prediction improvements do not consistently enhance variant effect predictions.

Conclusions:

  • Genomic deep learning model performance is not uniform across the genome.
  • Performance is notably reduced in cell type-specific accessible regions.
  • Strategies exist to enhance model performance for cell type-specific regulatory elements.