Ferroptotic stress promotes the accumulation of pro-inflammatory proximal tubular cells in maladaptive renal repair.

Abstract

Overwhelming lipid peroxidation induces ferroptotic stress and ferroptosis, a non-apoptotic form of regulated cell death that has been implicated in maladaptive renal repair in mice and humans. Using single-cell transcriptomic and mouse genetic approaches, we show that proximal tubular (PT) cells develop a molecularly distinct, pro-inflammatory state following injury. While these inflammatory PT cells transiently appear after mild injury and return to their original state without inducing fibrosis, after severe injury they accumulate and contribute to persistent inflammation. This transient inflammatory PT state significantly downregulates glutathione metabolism genes, making the cells vulnerable to ferroptotic stress. Genetic induction of high ferroptotic stress in these cells after mild injury leads to the accumulation of the inflammatory PT cells, enhancing inflammation and fibrosis. Our study broadens the roles of ferroptotic stress from being a trigger of regulated cell death to include the promotion and accumulation of proinflammatory cells that underlie maladaptive repair.

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Citation

Published Version (Please cite this version)

10.7554/elife.68603

Publication Info

Ide, Shintaro, Yoshihiko Kobayashi, Kana Ide, Sarah A Strausser, Koki Abe, Savannah Herbek, Lori L O'Brien, Steven D Crowley, et al. (2021). Ferroptotic stress promotes the accumulation of pro-inflammatory proximal tubular cells in maladaptive renal repair. eLife, 10. p. e68603. 10.7554/elife.68603 Retrieved from https://hdl.handle.net/10161/25529.

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Scholars@Duke

Crowley

Steven Daniel Crowley

Professor of Medicine

Our laboratory explores the contribution of the immune system and inflammatory mediators to the progression of target organ damage in the setting of cardiovascular disease. We are pursuing several related projects in this field:
(1) The actions of type 1 angiotensin receptors on specific immune cell populations in hypertension, target organ damage, and tissue fibrosis.
(2) Cell-specific actions of inflammatory cytokines in regulating blood pressure and end-organ injury.
(3) Mechanism through which dendritic cells regulate renal sodium reabsorption.
(4) The contributions of Wnt O-acylation to kidney scar formation.

Barisoni

Laura Barisoni

Professor of Pathology
Tata

Aleksandra Tata

Assistant Research Professor of Cell Biology
Tata

Purushothama Rao Tata

Associate Professor of Cell Biology

Lung regeneration
Lung stem cells
Cell plasticity
Organoid models
Lung Fibrosis
Single Cell Biology

Souma

Tomokazu Souma

Assistant Professor in Medicine

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