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Itaconate-producing neutrophils regulate local and systemic inflammation following trauma
Janna L. Crossley, Sonya Ostashevskaya-Gohstand, Stefano Comazzetto, Jessica S. Hook, Lei Guo, Neda Vishlaghi, Conan Juan, Lin Xu, Alexander R. Horswill, Gerta Hoxhaj, Jessica G. Moreland, Robert J. Tower, Benjamin Levi
Janna L. Crossley, Sonya Ostashevskaya-Gohstand, Stefano Comazzetto, Jessica S. Hook, Lei Guo, Neda Vishlaghi, Conan Juan, Lin Xu, Alexander R. Horswill, Gerta Hoxhaj, Jessica G. Moreland, Robert J. Tower, Benjamin Levi
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Research Article Immunology Inflammation

Itaconate-producing neutrophils regulate local and systemic inflammation following trauma

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Abstract

Modulation of the immune response to initiate and halt the inflammatory process occurs both at the site of injury as well as systemically. Due to the evolving role of cellular metabolism in regulating cell fate and function, tendon injuries that undergo normal and aberrant repair were evaluated by metabolic profiling to determine its impact on healing outcomes. Metabolomics revealed an increasing abundance of the immunomodulatory metabolite itaconate within the injury site. Subsequent single-cell RNA-Seq and molecular and metabolomic validation identified a highly mature neutrophil subtype, not macrophages, as the primary producers of itaconate following trauma. These mature itaconate-producing neutrophils were highly inflammatory, producing cytokines that promote local injury fibrosis before cycling back to the bone marrow. In the bone marrow, itaconate was shown to alter hematopoiesis, skewing progenitor cells down myeloid lineages, thereby regulating systemic inflammation. Therapeutically, exogenous itaconate was found to reduce injury-site inflammation, promoting tenogenic differentiation and impairing aberrant vascularization with disease-ameliorating effects. These results present an intriguing role for cycling neutrophils as a sensor of inflammation induced by injury — potentially regulating immune cell production in the bone marrow through delivery of endogenously produced itaconate — and demonstrate a therapeutic potential for exogenous itaconate following tendon injury

Authors

Janna L. Crossley, Sonya Ostashevskaya-Gohstand, Stefano Comazzetto, Jessica S. Hook, Lei Guo, Neda Vishlaghi, Conan Juan, Lin Xu, Alexander R. Horswill, Gerta Hoxhaj, Jessica G. Moreland, Robert J. Tower, Benjamin Levi

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Figure 4

Itaconate produced by stimulated neutrophils is delivered to the bone marrow.

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Itaconate produced by stimulated neutrophils is delivered to the bone ma...
(A) Expression of ACOD1 in human neutrophils isolated from peripheral blood and stimulated with TNF-α or varying doses of a cell membrane preparation from S. aureus (MRSA-CM). (B) Metabolomic profiling of itaconate in stimulated neutrophils. Proline is shown as a control. (C) Itaconate and lactate levels in cell bodies and conditioned media from freshly isolated, unstimulated, and TNF-α–stimulated human neutrophils. (D) Dot plot of Cxcr2 and Cxcr4 across different anatomical sites. (E) Expression of Cxcr2 and Cxcr4 across neutrophil pseudotime. (F) Confocal image of bone marrow from Cd169/Tomato mice showing injury-site neutrophils harvested from donor mice and dyed using a membrane label following i.v. injection (green) and Tomato+ macrophages (red) at indicated time points after injection. Scale bar: 25 μm. (G) Flow analysis of neutrophils and monocytes/macrophages from Cd169/Tomato mouse bone marrow injected i.v. with membrane-labeled neutrophils at indicated time points after injection. (H) Cxcr2/Cxcr4 ratio assessed by qPCR of neutrophils in vitro cultured with or without stimulation with TNF-α or MRSA-CM. Dotted line denotes a 1:1 ratio of Cxcr2 and Cxcr4 transcripts. (I) Relative expression of Acod1 assessed by qPCR in cultured neutrophils with or without TNF-α or MRSA-CM stimulation. Data are shown as mean ± SD. *P < 0.05, **P < 0.01, ***P < 0.001, determined by 2-way ANOVA followed by Tukey’s multiple-comparison test, relative to time 4 hours after stimulation (T4) unstimulated controls (A) or t0 (H and I) unless otherwise stated.

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