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Peroxisomal core structures segregate diverse metabolic pathways

Author

Listed:
  • Nils Bäcker

    (Philipps-University Marburg
    Philipps-University Marburg)

  • Julia Ast

    (Philipps-University Marburg)

  • Domenica Martorana

    (Philipps-University Marburg)

  • Christian Renicke

    (Philipps-University Marburg
    Stanford University School of Medicine)

  • Jil Berger

    (Philipps-University Marburg
    Philipps-University Marburg)

  • Cristopher-Nils Mais

    (Philipps-University Marburg
    Philipps-University Marburg)

  • Marvin Christ

    (Philipps-University Marburg
    Philipps-University Marburg)

  • Thorsten Stehlik

    (Philipps-University Marburg)

  • Thomas Heimerl

    (Philipps-University Marburg
    Philipps-University Marburg)

  • Valentin Wernet

    (KIT)

  • Christof Taxis

    (Philipps-University Marburg
    Health and Medical University Erfurt)

  • Jan Pané-Farré

    (Philipps-University Marburg
    Philipps-University Marburg)

  • Michael Bölker

    (Philipps-University Marburg
    Philipps-University Marburg)

  • Judith M. Klatt

    (Philipps-University Marburg
    Philipps-University Marburg
    Philipps-University Marburg & Max-Planck-Institute for terrestrial Microbiology)

  • Björn Sandrock

    (Philipps-University Marburg)

  • Kay Oliver Schink

    (University of Oslo, Montebello
    Oslo University Hospital, Montebello
    University of Oslo)

  • Gert Bange

    (Philipps-University Marburg
    Philipps-University Marburg
    Molecular Physiology of Microbes)

  • Johannes Freitag

    (Philipps-University Marburg
    Philipps-University Marburg)

Abstract

Peroxisomes are single membrane-bounded oxidative organelles with various metabolic functions including β-oxidation of fatty acids. Peroxisomes of many species confine certain metabolic enzymes into sub-compartments sometimes visible as electron dense cores. Why these structures form is largely unknown. Here, we report that in the smut fungus Ustilago maydis detergent resistant core structures are enriched for different enzymes excluding several key enzymes of the β-oxidation pathway. This confinement contributes to generation of peroxisome subpopulations that differ in their enzyme content. We identify short amino acid motifs necessary and sufficient for protein self-assembly into aggregates in vitro. The motifs trigger enrichment in cores in vivo and are active in mammalian cells. Perturbation of core assembly via variation of such motifs affects peroxisome function in U. maydis strains challenged with fatty acids. Thus, protein core structures serve to compartmentalize the lumen of peroxisomes thereby preventing interference of biochemical reactions. Metabolic compartmentalization of peroxisomes via assembly of specific proteins may occur in other organisms as well.

Suggested Citation

  • Nils Bäcker & Julia Ast & Domenica Martorana & Christian Renicke & Jil Berger & Cristopher-Nils Mais & Marvin Christ & Thorsten Stehlik & Thomas Heimerl & Valentin Wernet & Christof Taxis & Jan Pané-F, 2025. "Peroxisomal core structures segregate diverse metabolic pathways," Nature Communications, Nature, vol. 16(1), pages 1-16, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-57053-9
    DOI: 10.1038/s41467-025-57053-9
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    References listed on IDEAS

    as
    1. Zachary J. Wright & Bonnie Bartel, 2020. "Peroxisomes form intralumenal vesicles with roles in fatty acid catabolism and protein compartmentalization in Arabidopsis," Nature Communications, Nature, vol. 11(1), pages 1-13, December.
    2. Thorsten Stehlik & Marco Kremp & Jörg Kahnt & Michael Bölker & Johannes Freitag, 2020. "Peroxisomal targeting of a protein phosphatase type 2C via mitochondrial transit," Nature Communications, Nature, vol. 11(1), pages 1-11, December.
    3. Rini Ravindran & Isabel O. L. Bacellar & Xavier Castellanos-Girouard & Haytham M. Wahba & Zhenghao Zhang & James G. Omichinski & Lydia Kisley & Stephen W. Michnick, 2023. "Peroxisome biogenesis initiated by protein phase separation," Nature, Nature, vol. 617(7961), pages 608-615, May.
    4. Keun Woo Ryu & Tak Shun Fung & Daphne C. Baker & Michelle Saoi & Jinsung Park & Christopher A. Febres-Aldana & Rania G. Aly & Ruobing Cui & Anurag Sharma & Yi Fu & Olivia L. Jones & Xin Cai & H. Amali, 2024. "Cellular ATP demand creates metabolically distinct subpopulations of mitochondria," Nature, Nature, vol. 635(8039), pages 746-754, November.
    5. Laura Czech & Christopher-Nils Mais & Hanna Kratzat & Pinku Sarmah & Pietro Giammarinaro & Sven-Andreas Freibert & Hanna Folke Esser & Joanna Musial & Otto Berninghausen & Wieland Steinchen & Roland B, 2022. "Inhibition of SRP-dependent protein secretion by the bacterial alarmone (p)ppGpp," Nature Communications, Nature, vol. 13(1), pages 1-14, December.
    6. Johannes Freitag & Julia Ast & Michael Bölker, 2012. "Cryptic peroxisomal targeting via alternative splicing and stop codon read-through in fungi," Nature, Nature, vol. 485(7399), pages 522-525, May.
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