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Predictive biophysical neural network modeling of a compendium of in vivo transcription factor DNA binding profiles for Escherichia coli

Author

Listed:
  • Patrick Lally

    (44 Cummington Mall)

  • Laura Gómez-Romero

    (Ciudad de México
    Ciudad de México)

  • Víctor H. Tierrafría

    (44 Cummington Mall
    Cuernavaca)

  • Patricia Aquino

    (44 Cummington Mall)

  • Claire Rioualen

    (Cuernavaca)

  • Xiaoman Zhang

    (44 Cummington Mall)

  • Sunyoung Kim

    (Regina)

  • Gabriele Baniulyte

    (New York State Department of Health)

  • Jonathan Plitnick

    (New York State Department of Health)

  • Carol Smith

    (New York State Department of Health)

  • Mohan Babu

    (Regina)

  • Julio Collado-Vides

    (44 Cummington Mall
    Cuernavaca
    Universitat Pompeu Fabra (UPF))

  • Joseph T. Wade

    (New York State Department of Health
    SUNY)

  • James E. Galagan

    (44 Cummington Mall
    24 Cummington Mall)

Abstract

The DNA binding of most Escherichia coli Transcription Factors (TFs) has not been comprehensively mapped, and few have models that can quantitatively predict binding affinity. We report the global mapping of in vivo DNA binding for 139 E. coli TFs using ChIP-Seq. We use these data to train BoltzNet, a novel neural network that predicts TF binding energy from DNA sequence. BoltzNet mirrors a quantitative biophysical model and provides directly interpretable predictions genome-wide at nucleotide resolution. We use BoltzNet to quantitatively design novel binding sites, which we validate with biophysical experiments on purified protein. We generate models for 124 TFs that provide insight into global features of TF binding, including clustering of sites, the role of accessory bases, the relevance of weak sites, and the background affinity of the genome. Our paper provides new paradigms for studying TF-DNA binding and for the development of biophysically motivated neural networks.

Suggested Citation

  • Patrick Lally & Laura Gómez-Romero & Víctor H. Tierrafría & Patricia Aquino & Claire Rioualen & Xiaoman Zhang & Sunyoung Kim & Gabriele Baniulyte & Jonathan Plitnick & Carol Smith & Mohan Babu & Julio, 2025. "Predictive biophysical neural network modeling of a compendium of in vivo transcription factor DNA binding profiles for Escherichia coli," Nature Communications, Nature, vol. 16(1), pages 1-16, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-58862-8
    DOI: 10.1038/s41467-025-58862-8
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