Macrophage ferritin heavy chain/α-synuclein regulatory axis modulates ferroptosis during kidney injury
Tanima Chatterjee, Sarah Machado, Kellen Cowen, Mary E. Miller, Bronte Johnson, Yanfeng Zhang, Laura A. Volpicelli-Daley, Lauren A. Fielding, Rudradip Pattanayak, Frida Rosenblum, László Potor, György Balla, Jozsef Balla, Christian Faul, Abolfazl Zarjou
Tanima Chatterjee, Sarah Machado, Kellen Cowen, Mary E. Miller, Bronte Johnson, Yanfeng Zhang, Laura A. Volpicelli-Daley, Lauren A. Fielding, Rudradip Pattanayak, Frida Rosenblum, László Potor, György Balla, Jozsef Balla, Christian Faul, Abolfazl Zarjou
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Research Article Immunology Nephrology

Macrophage ferritin heavy chain/α-synuclein regulatory axis modulates ferroptosis during kidney injury

Abstract

Macrophages, endowed with remarkable phenotypic plasticity, are essential for orchestrating injury responses and regulating iron homeostasis. Given the central role of ferritin heavy chain (FtH) as a molecular rheostat linking iron sequestration to redox-dependent signaling, we examined how myeloid FtH governs renal iron trafficking and ensuing oxidative stress pathways during acute kidney injury (AKI). Transcriptome analysis revealed coupling of FtH deficiency in monocytes and macrophages with activation of ferroptosis, a regulated cell death associated with iron accumulation. Moreover, myeloid FtH deletion worsened AKI, increasing leukocyte infiltration and iron deposition, together with ferroptosis-associated gene induction, oxidative stress, and lipid peroxidation. Notably, α-synuclein (SNCA), an iron-binding protein and the main pathological driver of Parkinson’s disease, was robustly induced both by FtH deficiency and following AKI. Mechanistic studies showed that monomeric SNCA exhibits ferrireductase activity, amplifying redox cycling and promoting ferroptotic cell death. Furthermore, SNCA expression was elevated in kidney pathologies characterized by leukocyte expansion in both mouse models and human cohorts, suggesting that inflammatory microenvironments promote SNCA accumulation and redox imbalance. These findings define a macrophage FtH/SNCA regulatory axis as a key driver of ferroptosis in AKI, implicating SNCA as a pathological nexus between iron dyshomeostasis and inflammatory kidney injury.

Authors

Tanima Chatterjee, Sarah Machado, Kellen Cowen, Mary E. Miller, Bronte Johnson, Yanfeng Zhang, Laura A. Volpicelli-Daley, Lauren A. Fielding, Rudradip Pattanayak, Frida Rosenblum, László Potor, György Balla, Jozsef Balla, Christian Faul, Abolfazl Zarjou

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Figure 1

Myeloid FtH deletion triggers SNCA induction in macrophages.

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Myeloid FtH deletion triggers SNCA induction in macrophages. (A) Volcano...
(A) Volcano plot showing differentially expressed genes in the kidneys of WT (FtHfl/fl) and myeloid-specific FtH-deficient (FtHΔ/Δ) mice under quiescent conditions following bulk RNA-seq (n = 4 per group). (B) Heatmap illustrating the expression of genes that encode iron-binding proteins in kidneys of FtHfl/fl and FtHΔ/Δ mice using normalized reads obtained via bulk RNA-seq. (C) Representative immunohistochemistry using an anti-SNCA antibody in the kidney, spleen, and liver of FtHfl/fl and FtHΔ/Δ mice under homeostatic conditions. Black arrows in the FtHΔ/Δ kidney indicate SNCA-expressing interstitial cells. Inset: Higher magnification of a tubule with surrounding SNCA-expressing cells, marked with an asterisk. Scale bars: kidney, 100 μm; spleen, 200 μm; liver, 50 μm. (D) Immunofluorescence staining of SNCA and the myeloid marker CD11b in the kidney, spleen, and liver of FtHfl/fl and FtHΔ/Δ mice under baseline conditions. Scale bars: kidney, 25 μm; spleen, 200 μm; liver, 25 μm. (E) Representative Western blot of FtH and SNCA expression levels in FtHfl/fl and FtHΔ/Δ spleen at baseline. GAPDH was used as a loading control. (F and G) Densitometric analysis of spleen FtH and SNCA expression, normalized to GAPDH (n = 6 per genotype). (H) Serum SNCA levels measured by ELISA (n = 6 per genotype). **P < 0.01.