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Pr and Pfr structures of plant phytochrome A

Author

Listed:
  • Soshichiro Nagano

    (Justus Liebig University
    Free University of Berlin
    Max Planck Institute for Medical Research)

  • David Stetten

    (European Molecular Biology Laboratory (EMBL))

  • Kaoling Guan

    (Justus Liebig University
    University of Texas at Austin)

  • Peng-Yuan Chen

    (Justus Liebig University)

  • Chen Song

    (University of Leipzig)

  • Thomas Barends

    (Max Planck Institute for Medical Research)

  • Manfred S. Weiss

    (Macromolecular Crystallography)

  • Christian G. Feiler

    (Macromolecular Crystallography)

  • Katerina Dörner

    (European XFEL GmbH)

  • Iñaki Diego Martinez

    (European XFEL GmbH)

  • Robin Schubert

    (European XFEL GmbH)

  • Johan Bielecki

    (European XFEL GmbH)

  • Lea Brings

    (European XFEL GmbH)

  • Huijong Han

    (European XFEL GmbH)

  • Konstantin Kharitonov

    (European XFEL GmbH)

  • Chan Kim

    (European XFEL GmbH)

  • Marco Kloos

    (European XFEL GmbH)

  • Jayanath C. P. Koliyadu

    (European XFEL GmbH)

  • Faisal H. M. Koua

    (European XFEL GmbH)

  • Ekaterina Round

    (European XFEL GmbH)

  • Abhisakh Sarma

    (European XFEL GmbH)

  • Tokushi Sato

    (European XFEL GmbH)

  • Christina Schmidt

    (European XFEL GmbH)

  • Joana Valerio

    (European XFEL GmbH)

  • Agnieszka Wrona

    (European XFEL GmbH)

  • Joachim Schulz

    (European XFEL GmbH)

  • Raphael Wijn

    (European XFEL GmbH)

  • Romain Letrun

    (European XFEL GmbH)

  • Richard Bean

    (European XFEL GmbH)

  • Adrian Mancuso

    (European XFEL GmbH
    Diamond light source)

  • Karsten Heyne

    (Free University of Berlin)

  • Jon Hughes

    (Justus Liebig University
    Free University of Berlin)

Abstract

Phytochromes are biliprotein photoreceptors widespread amongst microorganisms and ubiquitous in plants where they control developmental processes as diverse as germination, stem elongation and floral induction through the photoconversion of inactive Pr to the Pfr signalling state. Here we report crystal structures of the chromophore-binding module of soybean phytochrome A, including ~2.2 Å XFEL structures of Pr and Pfr at ambient temperature and high resolution cryogenic structures of Pr. In the Pfr structure, the chromophore is exposed to the medium, the D-ring remaining α-facial following the likely clockwise photoflip. The chromophore shifts within its pocket, while its propionate side chains, their partners as well as three neighbouring tyrosines shift radically. Helices near the chromophore show substantial shifts that might represent components of the light signal. These changes reflect those in bacteriophytochromes despite their quite different signalling mechanisms, implying that fundamental aspects of phytochrome photoactivation have been repurposed for photoregulation in the eukaryotic plant.

Suggested Citation

  • Soshichiro Nagano & David Stetten & Kaoling Guan & Peng-Yuan Chen & Chen Song & Thomas Barends & Manfred S. Weiss & Christian G. Feiler & Katerina Dörner & Iñaki Diego Martinez & Robin Schubert & Joha, 2025. "Pr and Pfr structures of plant phytochrome A," Nature Communications, Nature, vol. 16(1), pages 1-12, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-60738-w
    DOI: 10.1038/s41467-025-60738-w
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    References listed on IDEAS

    as
    1. Jeremiah R. Wagner & Joseph S. Brunzelle & Katrina T. Forest & Richard D. Vierstra, 2005. "A light-sensing knot revealed by the structure of the chromophore-binding domain of phytochrome," Nature, Nature, vol. 438(7066), pages 325-331, November.
    2. Hua Li & E. Sethe Burgie & Zira T. K. Gannam & Huilin Li & Richard D. Vierstra, 2022. "Plant phytochrome B is an asymmetric dimer with unique signalling potential," Nature, Nature, vol. 604(7904), pages 127-133, April.
    3. Weixiao Yuan Wahlgren & Elin Claesson & Iida Tuure & Sergio Trillo-Muyo & Szabolcs Bódizs & Janne A. Ihalainen & Heikki Takala & Sebastian Westenhoff, 2022. "Structural mechanism of signal transduction in a phytochrome histidine kinase," Nature Communications, Nature, vol. 13(1), pages 1-8, December.
    4. Tomonao Matsushita & Nobuyoshi Mochizuki & Akira Nagatani, 2003. "Dimers of the N-terminal domain of phytochrome B are functional in the nucleus," Nature, Nature, vol. 424(6948), pages 571-574, July.
    5. Jon Hughes & Tilman Lamparter & Franz Mittmann & Elmar Hartmann & Wolfgang Gärtner & Annegret Wilde & Thomas Börner, 1997. "A prokaryotic phytochrome," Nature, Nature, vol. 386(6626), pages 663-663, April.
    6. E. Sethe Burgie & Katherine Basore & Michael J. Rau & Brock Summers & Alayna J. Mickles & Vadim Grigura & James A. J. Fitzpatrick & Richard D. Vierstra, 2024. "Signaling by a bacterial phytochrome histidine kinase involves a conformational cascade reorganizing the dimeric photoreceptor," Nature Communications, Nature, vol. 15(1), pages 1-16, December.
    7. Xiaojing Yang & Zhong Ren & Jane Kuk & Keith Moffat, 2011. "Temperature-scan cryocrystallography reveals reaction intermediates in bacteriophytochrome," Nature, Nature, vol. 479(7373), pages 428-432, November.
    8. Jaehoon Jeong & Yongju Lee & Giltsu Choi, 2025. "Both phytochrome A and phyB interact with PHYTOCHROME-INTERACTING FACTORs through an evolutionary conserved phyOPM-APA interaction," Nature Communications, Nature, vol. 16(1), pages 1-12, December.
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