Myeloid FtH Regulates Macrophage Response to Kidney Injury by Modulating Snca and Ferroptosis.

bioRxiv : the preprint server for biology Pub Date : 2025-03-28 DOI:10.1101/2025.03.25.645219

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

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Abstract

This study explored the role of myeloid ferritin heavy chain (FtH) in coordinating kidney iron trafficking in health and disease. Synuclein-α (Snca) was the sole iron-binding protein upregulated in response to myeloid FtH deletion (FtH ^Δ/Δ ). Following kidney injury, FtH ^Δ/Δ mice showed worsened kidney function. Transcriptome analysis revealed coupling of FtH deficiency with ferroptosis activation, a regulated cell death associated with iron accumulation. Adverse effects of ferroptosis were evidenced by upregulation of ferroptosis-related genes, increased oxidative stress markers, and significant iron deposition in kidney tissues. This iron buildup in FtH ^Δ/Δ kidneys stemmed from macrophage reprogramming into an iron-recycling phenotype, driven by Spic induction. Mechanistically, we establish that monomeric Snca functions as a ferrireductase catalyst, intensifying oxidative stress and triggering ferroptosis. Additionally, Snca accumulates in kidney diseases distinguished by leukocyte expansion across species. These findings position myeloid FtH as a pivotal orchestrator of the FtH-Snca-Spic axis driving macrophage reprogramming and kidney injury.

Highlights: Myeloid FtH deficiency drives kidney injury via activation of ferroptosisMΦ FtH deficiency induces Snca, linking iron dysregulation to MΦ function and response to kidney injuryFerrireductase activity of monomeric Snca augments oxidative stress, promoting lipid peroxidation and ferroptosis.

In brief: MΦ FtH modulates Snca and Spic to coordinate the injury response, linking iron trafficking to ferroptosis-induced kidney injury.

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髓质 FtH 通过调节 Snca 和铁凋亡调节巨噬细胞对肾损伤的反应

本研究探讨髓系铁蛋白重链（FtH）在健康和疾病中协调肾铁运输中的作用。Synuclein-α (Snca)是唯一在髓细胞FtH缺失反应中上调的铁结合蛋白（FtH Δ/Δ）。肾损伤后，FtH Δ/Δ小鼠肾功能恶化。转录组分析揭示了FtH缺乏与铁凋亡激活的耦合，这是一种与铁积累相关的受调节的细胞死亡。铁中毒相关基因上调，氧化应激标志物增加，肾组织铁沉积显著，证明了铁中毒的不良影响。FtH Δ/Δ肾脏中的铁积累源于巨噬细胞重编程为铁循环表型，由Spic诱导。从机制上讲，我们确定单体Snca作为铁还原酶催化剂，增强氧化应激并触发铁凋亡。此外，Snca在肾脏疾病中积累，其特征是白细胞跨物种扩张。这些发现表明髓系FtH是FtH- snca - spic轴驱动巨噬细胞重编程和肾损伤的关键协调者。重点：髓系FtH缺乏通过ferroptosisMΦ激活驱动肾损伤FtH缺乏诱导Snca，将铁调节失调与MΦ功能和肾损伤反应联系起来单体Snca的铁还原酶活性增加氧化应激，促进脂质过氧化和铁凋亡。简而言之：MΦ FtH调节Snca和Spic来协调损伤反应，将铁运输与铁中毒引起的肾损伤联系起来。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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bioRxiv : the preprint server for biology

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