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The evolution, evolvability and engineering of gene regulatory DNA

Author

Listed:
  • Eeshit Dhaval Vaishnav

    (Massachusetts Institute of Technology
    Broad Institute of MIT and Harvard)

  • Carl G. Boer

    (University of British Columbia
    Broad Institute of MIT and Harvard)

  • Jennifer Molinet

    (Universidad de Santiago de Chile
    Millennium Institute for Integrative Biology (iBio))

  • Moran Yassour

    (Broad Institute of MIT and Harvard
    The Hebrew University of Jerusalem
    The Hebrew University of Jerusalem)

  • Lin Fan

    (Broad Institute of MIT and Harvard)

  • Xian Adiconis

    (Broad Institute of MIT and Harvard
    Broad Institute of MIT and Harvard)

  • Dawn A. Thompson

    (Broad Institute of MIT and Harvard)

  • Joshua Z. Levin

    (Broad Institute of MIT and Harvard
    Broad Institute of MIT and Harvard)

  • Francisco A. Cubillos

    (Universidad de Santiago de Chile
    Millennium Institute for Integrative Biology (iBio))

  • Aviv Regev

    (Broad Institute of MIT and Harvard
    Massachusetts Institute of Technology
    Genentech)

Abstract

Mutations in non-coding regulatory DNA sequences can alter gene expression, organismal phenotype and fitness1–3. Constructing complete fitness landscapes, in which DNA sequences are mapped to fitness, is a long-standing goal in biology, but has remained elusive because it is challenging to generalize reliably to vast sequence spaces4–6. Here we build sequence-to-expression models that capture fitness landscapes and use them to decipher principles of regulatory evolution. Using millions of randomly sampled promoter DNA sequences and their measured expression levels in the yeast Saccharomyces cerevisiae, we learn deep neural network models that generalize with excellent prediction performance, and enable sequence design for expression engineering. Using our models, we study expression divergence under genetic drift and strong-selection weak-mutation regimes to find that regulatory evolution is rapid and subject to diminishing returns epistasis; that conflicting expression objectives in different environments constrain expression adaptation; and that stabilizing selection on gene expression leads to the moderation of regulatory complexity. We present an approach for using such models to detect signatures of selection on expression from natural variation in regulatory sequences and use it to discover an instance of convergent regulatory evolution. We assess mutational robustness, finding that regulatory mutation effect sizes follow a power law, characterize regulatory evolvability, visualize promoter fitness landscapes, discover evolvability archetypes and illustrate the mutational robustness of natural regulatory sequence populations. Our work provides a general framework for designing regulatory sequences and addressing fundamental questions in regulatory evolution.

Suggested Citation

  • Eeshit Dhaval Vaishnav & Carl G. Boer & Jennifer Molinet & Moran Yassour & Lin Fan & Xian Adiconis & Dawn A. Thompson & Joshua Z. Levin & Francisco A. Cubillos & Aviv Regev, 2022. "The evolution, evolvability and engineering of gene regulatory DNA," Nature, Nature, vol. 603(7901), pages 455-463, March.
  • Handle: RePEc:nat:nature:v:603:y:2022:i:7901:d:10.1038_s41586-022-04506-6
    DOI: 10.1038/s41586-022-04506-6
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    Cited by:

    1. Jan Zrimec & Xiaozhi Fu & Azam Sheikh Muhammad & Christos Skrekas & Vykintas Jauniskis & Nora K. Speicher & Christoph S. Börlin & Vilhelm Verendel & Morteza Haghir Chehreghani & Devdatt Dubhashi & Ver, 2022. "Controlling gene expression with deep generative design of regulatory DNA," Nature Communications, Nature, vol. 13(1), pages 1-17, December.
    2. Shumin Wang & Xin Jiang & Muhammad Bilawal Khaskheli, 2024. "The Role of Technology in the Digital Economy’s Sustainable Development of Hainan Free Trade Port and Genetic Testing: Cloud Computing and Digital Law," Sustainability, MDPI, vol. 16(14), pages 1-20, July.
    3. Lu Wu & Xu-Wen Wang & Zining Tao & Tong Wang & Wenlong Zuo & Yu Zeng & Yang-Yu Liu & Lei Dai, 2024. "Data-driven prediction of colonization outcomes for complex microbial communities," Nature Communications, Nature, vol. 15(1), pages 1-15, December.
    4. Evangelos-Marios Nikolados & Arin Wongprommoon & Oisin Mac Aodha & Guillaume Cambray & Diego A. Oyarzún, 2022. "Accuracy and data efficiency in deep learning models of protein expression," Nature Communications, Nature, vol. 13(1), pages 1-12, December.

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