<p>Ferritin, composed of heavy chain (FTH1) and light chain (FTL) subunits, is a key intracellular iron storage protein, but the origin and biological role of extracellular ferritin (ex-ferritin) remain poorly understood. Elevated serum ex-ferritin is associated with worse outcomes in acute respiratory distress syndrome (ARDS). Here, we show that both FTH1 and FTL are significantly enriched in the serum, blood monocytes, and alveolar macrophages (AM) of individuals with ARDS, findings we replicate in a murine hyperoxia-induced acute lung injury model. Myeloid-specific FTH1 (<i>Fth1</i><sup><i>ΔLysM</i></sup>) deletion attenuates lung injury, and is associated with reduced macrophage ferroptosis, altered airway inflammatory responses, lower extracellular iron and compensatory secretion of FTL-ex-ferritin. While pharmacologic ferroptosis inhibition prior to hyperoxia had no effect, transplantation of FTL-ex-ferritin-enriched bronchoalveolar lavage fluid conferred protection from lung injury. These findings identify macrophage ferritin metabolism and ex-ferritin secretion as critical regulators of lung injury, offering new insights into the pathobiology of ARDS.</p>

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Targeting macrophage ferritin heavy chain mitigates ferroptosis and lung injury in experimental acute respiratory distress syndrome

  • William Z. Zhang,
  • Kihwan Kim,
  • Divya Bhatia,
  • Lynne Faherty,
  • Will Simmons,
  • Eleni Kallinos,
  • Sebastian E. Carrasco,
  • Katherine L. Hoffman,
  • Sean Houghton,
  • Chia-Lang Hsu,
  • Leora Haber,
  • Cem Meydan,
  • Christopher E. Mason,
  • Ananda S. Mirchandani,
  • Sarah R. Walmsley,
  • Parag Goyal,
  • Kuei-Pin Chung,
  • Karla V. Ballman,
  • David Redmond,
  • Joseph D. Mancias,
  • Augustine M. K. Choi,
  • Edward J. Schenck,
  • Maria Plataki,
  • Suzanne M. Cloonan

摘要

Ferritin, composed of heavy chain (FTH1) and light chain (FTL) subunits, is a key intracellular iron storage protein, but the origin and biological role of extracellular ferritin (ex-ferritin) remain poorly understood. Elevated serum ex-ferritin is associated with worse outcomes in acute respiratory distress syndrome (ARDS). Here, we show that both FTH1 and FTL are significantly enriched in the serum, blood monocytes, and alveolar macrophages (AM) of individuals with ARDS, findings we replicate in a murine hyperoxia-induced acute lung injury model. Myeloid-specific FTH1 (Fth1ΔLysM) deletion attenuates lung injury, and is associated with reduced macrophage ferroptosis, altered airway inflammatory responses, lower extracellular iron and compensatory secretion of FTL-ex-ferritin. While pharmacologic ferroptosis inhibition prior to hyperoxia had no effect, transplantation of FTL-ex-ferritin-enriched bronchoalveolar lavage fluid conferred protection from lung injury. These findings identify macrophage ferritin metabolism and ex-ferritin secretion as critical regulators of lung injury, offering new insights into the pathobiology of ARDS.