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Microbe capture by splenic macrophages triggers sepsis via T cell-death-dependent neutrophil lifespan shortening

Author

Listed:
  • Marianna Ioannou

    (Antimicrobial Defence Laboratory)

  • Dennis Hoving

    (Antimicrobial Defence Laboratory)

  • Iker Valle Aramburu

    (Antimicrobial Defence Laboratory)

  • Mia I. Temkin

    (Antimicrobial Defence Laboratory)

  • Nathalia M. Vasconcelos

    (Antimicrobial Defence Laboratory)

  • Theodora-Dorita Tsourouktsoglou

    (Antimicrobial Defence Laboratory)

  • Qian Wang

    (Antimicrobial Defence Laboratory)

  • Stefan Boeing

    (Bioinformatics and Biostatistics)

  • Robert Goldstone

    (Advanced Sequencing)

  • Spyros Vernardis

    (Molecular Biology of Metabolism Laboratory)

  • Vadim Demichev

    (Molecular Biology of Metabolism Laboratory)

  • Markus Ralser

    (Molecular Biology of Metabolism Laboratory
    Department of Biochemistry)

  • Sascha David

    (University Hospital Zurich)

  • Klaus Stahl

    (Hepatology and Endocrinology, Medical School Hannover)

  • Christian Bode

    (University Hospital Bonn)

  • Venizelos Papayannopoulos

    (Antimicrobial Defence Laboratory)

Abstract

The mechanisms linking systemic infection to hyperinflammation and immune dysfunction in sepsis are poorly understood. Extracellular histones promote sepsis pathology, but their source and mechanism of action remain unclear. Here, we show that by controlling fungi and bacteria captured by splenic macrophages, neutrophil-derived myeloperoxidase attenuates sepsis by suppressing histone release. In systemic candidiasis, microbial capture via the phagocytic receptor SIGNR1 neutralizes myeloperoxidase by facilitating marginal zone infiltration and T cell death-dependent histone release. Histones and hyphae induce cytokines in adjacent CD169 macrophages including G-CSF that selectively depletes mature Ly6Ghigh neutrophils by shortening their lifespan in favour of immature Ly6Glow neutrophils with a defective oxidative burst. In sepsis patient plasma, these mediators shorten mature neutrophil lifespan and correlate with neutrophil mortality markers. Consequently, high G-CSF levels and neutrophil lifespan shortening activity are associated with sepsis patient mortality. Hence, by exploiting phagocytic receptors, pathogens degrade innate and adaptive immunity through the detrimental impact of downstream effectors on neutrophil lifespan.

Suggested Citation

  • Marianna Ioannou & Dennis Hoving & Iker Valle Aramburu & Mia I. Temkin & Nathalia M. Vasconcelos & Theodora-Dorita Tsourouktsoglou & Qian Wang & Stefan Boeing & Robert Goldstone & Spyros Vernardis & V, 2022. "Microbe capture by splenic macrophages triggers sepsis via T cell-death-dependent neutrophil lifespan shortening," Nature Communications, Nature, vol. 13(1), pages 1-24, December.
    • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-32320-1
    DOI: 10.1038/s41467-022-32320-1
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    Cited by:

    1. Sudipta Das & Tomasz W. Kaminski & Brent T. Schlegel & William Bain & Sanmei Hu & Akruti Patel & Sagar L. Kale & Kong Chen & Janet S. Lee & Rama K. Mallampalli & Valerian E. Kagan & Dhivyaa Rajasundar, 2024. "Neutrophils and galectin-3 defend mice from lethal bacterial infection and humans from acute respiratory failure," Nature Communications, Nature, vol. 15(1), pages 1-20, December.

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