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Macrophages disseminate pathogen associated molecular patterns through the direct extracellular release of the soluble content of their phagolysosomes

Author

Listed:
  • Catherine J. Greene

    (University of Calgary
    University of Calgary)

  • Jenny A. Nguyen

    (University of Calgary)

  • Samuel M. Cheung

    (University of Calgary)

  • Corey R. Arnold

    (University of Calgary)

  • Dale R. Balce

    (University of Calgary
    Washington University School of Medicine
    Vir Biotechnology)

  • Ya Ting Wang

    (Washington University School of Medicine)

  • Adrian Soderholm

    (University of Calgary)

  • Neil McKenna

    (University of Calgary)

  • Devin Aggarwal

    (University of Calgary)

  • Rhiannon I. Campden

    (University of Calgary)

  • Benjamin W. Ewanchuk

    (University of Calgary)

  • Herbert W. Virgin

    (Washington University School of Medicine
    Vir Biotechnology)

  • Robin M. Yates

    (University of Calgary
    University of Calgary
    University of Calgary)

Abstract

Recognition of pathogen-or-damage-associated molecular patterns is critical to inflammation. However, most pathogen-or-damage-associated molecular patterns exist within intact microbes/cells and are typically part of non-diffusible, stable macromolecules that are not optimally immunostimulatory or available for immune detection. Partial digestion of microbes/cells following phagocytosis potentially generates new diffusible pathogen-or-damage-associated molecular patterns, however, our current understanding of phagosomal biology would have these molecules sequestered and destroyed within phagolysosomes. Here, we show the controlled release of partially-digested, soluble material from phagolysosomes of macrophages through transient, iterative fusion-fission events between mature phagolysosomes and the plasma membrane, a process we term eructophagy. Eructophagy is most active in proinflammatory macrophages and further induced by toll like receptor engagement. Eructophagy is mediated by genes encoding proteins required for autophagy and can activate vicinal cells by release of phagolysosomally-processed, partially-digested pathogen associated molecular patterns. We propose that eructophagy allows macrophages to amplify local inflammation through the processing and dissemination of pathogen-or-damage-associated molecular patterns.

Suggested Citation

  • Catherine J. Greene & Jenny A. Nguyen & Samuel M. Cheung & Corey R. Arnold & Dale R. Balce & Ya Ting Wang & Adrian Soderholm & Neil McKenna & Devin Aggarwal & Rhiannon I. Campden & Benjamin W. Ewanchu, 2022. "Macrophages disseminate pathogen associated molecular patterns through the direct extracellular release of the soluble content of their phagolysosomes," Nature Communications, Nature, vol. 13(1), pages 1-17, December.
    • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-30654-4
    DOI: 10.1038/s41467-022-30654-4
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    References listed on IDEAS

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    1. Miguel A. Sanjuan & Christopher P. Dillon & Stephen W. G. Tait & Simon Moshiach & Frank Dorsey & Samuel Connell & Masaaki Komatsu & Keiji Tanaka & John L. Cleveland & Sebo Withoff & Douglas R. Green, 2007. "Toll-like receptor signalling in macrophages links the autophagy pathway to phagocytosis," Nature, Nature, vol. 450(7173), pages 1253-1257, December.
    2. Taichi Hara & Kenji Nakamura & Makoto Matsui & Akitsugu Yamamoto & Yohko Nakahara & Rika Suzuki-Migishima & Minesuke Yokoyama & Kenji Mishima & Ichiro Saito & Hideyuki Okano & Noboru Mizushima, 2006. "Suppression of basal autophagy in neural cells causes neurodegenerative disease in mice," Nature, Nature, vol. 441(7095), pages 885-889, June.
    3. Masaaki Komatsu & Satoshi Waguri & Tomoki Chiba & Shigeo Murata & Jun-ichi Iwata & Isei Tanida & Takashi Ueno & Masato Koike & Yasuo Uchiyama & Eiki Kominami & Keiji Tanaka, 2006. "Loss of autophagy in the central nervous system causes neurodegeneration in mice," Nature, Nature, vol. 441(7095), pages 880-884, June.
    4. Ken Cadwell & John Y. Liu & Sarah L. Brown & Hiroyuki Miyoshi & Joy Loh & Jochen K. Lennerz & Chieko Kishi & Wumesh Kc & Javier A. Carrero & Steven Hunt & Christian D. Stone & Elizabeth M. Brunt & Ram, 2008. "A key role for autophagy and the autophagy gene Atg16l1 in mouse and human intestinal Paneth cells," Nature, Nature, vol. 456(7219), pages 259-263, November.
    5. Jiajie Diao & Rong Liu & Yueguang Rong & Minglei Zhao & Jing Zhang & Ying Lai & Qiangjun Zhou & Livia M. Wilz & Jianxu Li & Sandro Vivona & Richard A. Pfuetzner & Axel T. Brunger & Qing Zhong, 2015. "ATG14 promotes membrane tethering and fusion of autophagosomes to endolysosomes," Nature, Nature, vol. 520(7548), pages 563-566, April.
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