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The functional proteome landscape of Escherichia coli

Author

Listed:
  • André Mateus

    (European Molecular Biology Laboratory (EMBL))

  • Johannes Hevler

    (European Molecular Biology Laboratory (EMBL))

  • Jacob Bobonis

    (European Molecular Biology Laboratory (EMBL)
    Heidelberg University)

  • Nils Kurzawa

    (European Molecular Biology Laboratory (EMBL)
    Heidelberg University)

  • Malay Shah

    (European Molecular Biology Laboratory (EMBL))

  • Karin Mitosch

    (European Molecular Biology Laboratory (EMBL))

  • Camille V. Goemans

    (European Molecular Biology Laboratory (EMBL))

  • Dominic Helm

    (European Molecular Biology Laboratory (EMBL))

  • Frank Stein

    (European Molecular Biology Laboratory (EMBL))

  • Athanasios Typas

    (European Molecular Biology Laboratory (EMBL))

  • Mikhail M. Savitski

    (European Molecular Biology Laboratory (EMBL))

Abstract

Recent developments in high-throughput reverse genetics1,2 have revolutionized our ability to map gene function and interactions3–6. The power of these approaches depends on their ability to identify functionally associated genes, which elicit similar phenotypic changes across several perturbations (chemical, environmental or genetic) when knocked out7–9. However, owing to the large number of perturbations, these approaches have been limited to growth or morphological readouts10. Here we use a high-content biochemical readout, thermal proteome profiling11, to measure the proteome-wide protein abundance and thermal stability in response to 121 genetic perturbations in Escherichia coli. We show that thermal stability, and therefore the state and interactions of essential proteins, is commonly modulated, raising the possibility of studying a protein group that is particularly inaccessible to genetics. We find that functionally associated proteins have coordinated changes in abundance and thermal stability across perturbations, owing to their co-regulation and physical interactions (with proteins, metabolites or cofactors). Finally, we provide mechanistic insights into previously determined growth phenotypes12 that go beyond the deleted gene. These data represent a rich resource for inferring protein functions and interactions.

Suggested Citation

  • André Mateus & Johannes Hevler & Jacob Bobonis & Nils Kurzawa & Malay Shah & Karin Mitosch & Camille V. Goemans & Dominic Helm & Frank Stein & Athanasios Typas & Mikhail M. Savitski, 2020. "The functional proteome landscape of Escherichia coli," Nature, Nature, vol. 588(7838), pages 473-478, December.
  • Handle: RePEc:nat:nature:v:588:y:2020:i:7838:d:10.1038_s41586-020-3002-5
    DOI: 10.1038/s41586-020-3002-5
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    Cited by:

    1. Cristina Sayago & Jana Sánchez-Wandelmer & Fernando García & Begoña Hurtado & Vanesa Lafarga & Patricia Prieto & Eduardo Zarzuela & Pilar Ximénez-Embún & Sagrario Ortega & Diego Megías & Oscar Fernánd, 2023. "Decoding protein methylation function with thermal stability analysis," Nature Communications, Nature, vol. 14(1), pages 1-18, December.
    2. Marta Ukleja & Lara Kricks & Gabriel Torrens & Ilaria Peschiera & Ines Rodrigues-Lopes & Marcin Krupka & Julia García-Fernández & Roberto Melero & Rosa Campo & Ana Eulalio & André Mateus & María López, 2024. "Flotillin-mediated stabilization of unfolded proteins in bacterial membrane microdomains," Nature Communications, Nature, vol. 15(1), pages 1-21, December.
    3. Sandhya Malla & Kanchan Kumari & Carlos A. García-Prieto & Jonatan Caroli & Anna Nordin & Trinh T. T. Phan & Devi Prasad Bhattarai & Carlos Martinez-Gamero & Eshagh Dorafshan & Stephanie Stransky & Da, 2024. "The scaffolding function of LSD1 controls DNA methylation in mouse ESCs," Nature Communications, Nature, vol. 15(1), pages 1-24, December.

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