Iron therapy mitigates chronic kidney disease progression by regulating intracellular iron status of kidney macrophages
Edwin Patino, Divya Bhatia, Steven Z. Vance, Ada Antypiuk, Rie Uni, Chantalle Campbell, Carlo G. Castillo, Shahd Jaouni, Francesca Vinchi, Mary E. Choi, Oleh Akchurin
Edwin Patino, Divya Bhatia, Steven Z. Vance, Ada Antypiuk, Rie Uni, Chantalle Campbell, Carlo G. Castillo, Shahd Jaouni, Francesca Vinchi, Mary E. Choi, Oleh Akchurin
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Research Article Nephrology

Iron therapy mitigates chronic kidney disease progression by regulating intracellular iron status of kidney macrophages

Abstract

Systemic iron metabolism is disrupted in chronic kidney disease (CKD). However, little is known about local kidney iron homeostasis and its role in kidney fibrosis. Kidney-specific effects of iron therapy in CKD also remain elusive. Here, we elucidate the role of macrophage iron status in kidney fibrosis and demonstrate that it is a potential therapeutic target. In CKD, kidney macrophages exhibited depletion of labile iron pool (LIP) and induction of transferrin receptor 1, indicating intracellular iron deficiency. Low LIP in kidney macrophages was associated with their defective antioxidant response and proinflammatory polarization. Repletion of LIP in kidney macrophages through knockout of ferritin heavy chain (Fth1) reduced oxidative stress and mitigated fibrosis. Similar to Fth1 knockout, iron dextran therapy, through replenishing macrophage LIP, reduced oxidative stress, decreased the production of proinflammatory cytokines, and alleviated kidney fibrosis. Interestingly, iron markedly decreased TGF-β expression and suppressed TGF-β–driven fibrotic response of macrophages. Iron dextran therapy and FtH suppression had an additive protective effect against fibrosis. Adoptive transfer of iron-loaded macrophages alleviated kidney fibrosis, validating the protective effect of iron-replete macrophages in CKD. Thus, targeting intracellular iron deficiency of kidney macrophages in CKD can serve as a therapeutic opportunity to mitigate disease progression.

Authors

Edwin Patino, Divya Bhatia, Steven Z. Vance, Ada Antypiuk, Rie Uni, Chantalle Campbell, Carlo G. Castillo, Shahd Jaouni, Francesca Vinchi, Mary E. Choi, Oleh Akchurin

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Figure 2

Myeloid-specific deletion of Fth1 improves iron deficiency of kidney macrophages and mitigates kidney fibrosis.

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Myeloid-specific deletion of Fth1 improves iron deficiency of kidney mac...
(A) Myeloid Fth1 deletion replenished the intracellular LIP and reduced TfR1 expression by kidney macrophages; n = 3 per group. One-tailed t test. *P < 0.05. (B) ROS and lipid peroxidation in kidney macrophages of CKD Fth1LysM–/– and Fth1LysM+/– CKD mice; n = 3–5 per group. (C) Expression of IL-1β and TNF-α by kidney macrophages in 2 groups of mice; n = 4–8 per group. (D) Fibrosis markers TGF-β and α–smooth muscle actin (α-SMA) in kidney macrophages of CKD Fth1LysM–/– and Fth1LysM+/– CKD mice; n = 5–9 per group. (E) Representative images of Masson’s trichrome staining of kidney sections in 2 groups of mice; the quantification is shown as kidney fibrosis score; n = 5 per group. (F) Biomarkers of the kidney function: urine albumin to creatinine ratio (ACR), blood urea nitrogen (BUN), and serum cystatin C in CKD Fth1LysM–/– and Fth1LysM+/– mice; n = 5 per group. ACR and cystatin C were measured after 4 weeks of adenine diet, BUN after 8 weeks of adenine diet. Scale bars, 100 μm. Error bars represent SEM. Data were analyzed using t test. *P < 0.05; **P < 0.01.