Acute kidney injury triggers hypoxemia by lung intravascular neutrophil retention that reduces capillary blood flow
Yohei Komaru, Liang Ning, Carine Lama, Anusha Suresh, Eirini Kefaloyianni, Mark J. Miller, Shinichi Kawana, Hailey M. Shepherd, Wenjun Li, Daniel Kreisel, Andreas Herrlich
Yohei Komaru, Liang Ning, Carine Lama, Anusha Suresh, Eirini Kefaloyianni, Mark J. Miller, Shinichi Kawana, Hailey M. Shepherd, Wenjun Li, Daniel Kreisel, Andreas Herrlich
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Research Article Inflammation Nephrology Pulmonology

Acute kidney injury triggers hypoxemia by lung intravascular neutrophil retention that reduces capillary blood flow

Abstract

Sterile acute kidney injury (AKI) is common in the clinic and frequently associated with unexplained hypoxemia that does not improve with dialysis. AKI induces remote lung inflammation with neutrophil recruitment in mice and humans, but which cellular cues establish neutrophilic inflammation and how it contributes to hypoxemia is not known. Here we report that AKI induced rapid intravascular neutrophil retention in lung alveolar capillaries without extravasation into tissue or alveoli, causing hypoxemia by reducing lung capillary blood flow in the absence of substantial lung interstitial or alveolar edema. In contrast to direct ischemic lung injury, lung neutrophil recruitment during remote lung inflammation did not require cues from intravascular nonclassical monocytes or tissue-resident alveolar macrophages. Instead, lung neutrophil retention depended on the neutrophil chemoattractant CXCL2 released by activated classical monocytes. Comparative single-cell RNA-Seq analysis of direct and remote lung inflammation revealed that alveolar macrophages were highly activated and produced CXCL2 only in direct lung inflammation. Establishing a CXCL2 gradient into the alveolus by intratracheal CXCL2 administration during AKI-induced remote lung inflammation enabled neutrophils to extravasate. We thus discovered important differences in lung neutrophil recruitment in direct versus remote lung inflammation and identified lung capillary neutrophil retention that negatively affected oxygenation by causing a ventilation-perfusion mismatch as a driver of AKI-induced hypoxemia.

Authors

Yohei Komaru, Liang Ning, Carine Lama, Anusha Suresh, Eirini Kefaloyianni, Mark J. Miller, Shinichi Kawana, Hailey M. Shepherd, Wenjun Li, Daniel Kreisel, Andreas Herrlich

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Figure 2

Intravascular lung capillary “neutrophil train” formation after AKI.

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Intravascular lung capillary “neutrophil train” formation after AKI. (A)...
(A) Intravital 2-photon imaging of sham-treated and AKI lungs 2 hours after AKI using Ccr2gfp/+ mice and in vivo staining of neutrophils; CCR2+ monocytes (green), Ly6G+ neutrophils (red). Blood flow was assessed with 1 μm beads (white), and lung capillary circulation was labeled by i.v. injection of quantum dots (purple). The magnified inset image shows a neutrophil train in a lung capillary, illustrating vessel-occlusive accumulation of neutrophil trains attached to CCR2+ monocyte “locomotives.” Full videos are available in the supplemental materials. Scale bars: 100 μm; original magnification, x3.25 (inset). (BD) Quantification of intravital imaging videos: speed of neutrophil rolling (B), the number of static beads (C), and the average distance between CCR2+ monocytes and neutrophils (D). n = 4 per group. *P < 0.05 and **P < 0.01, by unpaired, 2-tailed Student’s t test. (E) Lung intravital time-lapse 3D image immediately after AKI (5–10 minutes). Magnified images on the right illustrate the process of neutrophil (red) train formation in the presence of a CCR2+ monocyte (green). Scale bar: 100μm A full time-lapse video is available as Supplemental Video 3. Scale bar: 100 μm; original magnification, x3.25 (inset). All data represent the mean ± SD (BE).