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Identifying transcriptomic correlates of histology using deep learning.

Liviu Badea1, Emil Stănescu1

  • 1Artificial Intelligence and Bioinformatics Group, National Institute for Research and Development in Informatics, Bucharest, Romania.

Plos One
|November 25, 2020
PubMed
Summary
This summary is machine-generated.

Deep learning automatically identifies visual tissue features from images, linking them to gene expression. This approach overcomes subjective analysis, enabling precise transcriptome-phenotype correlations for biological discovery.

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Area of Science:

  • Computational biology
  • Genomics
  • Histopathology

Background:

  • Linking gene expression to biological phenotypes is crucial but challenging.
  • Traditional methods rely on subjective interpretation or extensive gene perturbations.
  • Current approaches struggle to bridge the gap between molecular data and tissue-level organization.

Purpose of the Study:

  • To develop a Deep Learning (DL) model for objective identification of histological features.
  • To establish quantifiable correlations between visual tissue phenotypes and gene expression profiles (transcriptomes).
  • To enhance the interpretability and explainability of DL-derived biological insights.

Main Methods:

  • Utilized a dataset of whole slide images and matching gene expression data from 39 normal tissue types.
  • Developed a DL-based tissue classifier achieving 94% accuracy.
  • Identified genes correlating with DL-inferred visual features and visualized these features.

Main Results:

  • DL successfully classified tissue types with high accuracy.
  • The model automatically derived biologically interpretable visual features correlated with transcriptomes.
  • Visualizations of inferred features aligned with immunohistochemistry data, confirming biological relevance.

Conclusions:

  • Deep learning offers a powerful, objective approach to link histology and genomics.
  • This method facilitates the discovery of novel transcriptome-phenotype correlations.
  • The study provides a foundation for bridging molecular and cellular levels of biological organization.