Abstract

Immediately after a wound, macrophages are activated and change their phenotypes in reaction to danger signals released from the damaged tissues. The cues that contribute to macrophage activation after wounding in vivo are still poorly understood. Calcium signaling and Reactive Oxygen Species (ROS), mainly hydrogen peroxide, are conserved early wound signals that emanate from the wound and guide neutrophils within tissues up to the wound. However, the role of these signals in the recruitment and the activation of macrophages is elusive. Here we used the transparent zebrafish larva as a tractable vertebrate system to decipher the signaling cascade necessary for macrophage recruitment and activation after the injury of the caudal fin fold. By using transgenic reporter lines to track pro-inflammatory activated macrophages combined with high-resolutive microscopy, we tested the role of Ca²⁺ and ROS signaling in macrophage activation. By inhibiting intracellular Ca²⁺ released from the ER stores, we showed that macrophage recruitment and activation towards pro-inflammatory phenotypes are impaired. By contrast, ROS are only necessary for macrophage activation independently on calcium. Using genetic depletion of neutrophils, we showed that neutrophils are not essential for macrophage recruitment and activation. Finally, we identified Src family kinases, Lyn and Yrk and NF-κB as key regulators of macrophage activation in vivo, with Lyn and ROS presumably acting in the same signaling pathway. This study describes a molecular mechanism by which early wound signals drive macrophage polarization and suggests unique therapeutic targets to control macrophage activity during diseases.

Highlights

  • Tissue wounding induces an immediate response necessary to restore epithelial barriers and stop pathogen entry

  • This simplistic view of macrophage polarization has been challenged by the discovery that macrophage phenotypes encompass a larger array of activation states and profiles, beyond M1 and M2, in vitro and in vivo, suggesting that more than 2 macrophage phenotypes are involved in the wound healing process [18,19,20]

  • We have shown that the Src family kinase (SFK), Lyn and Yes-related kinase (Yrk) are important for the process of proinflammatory macrophage activation

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Summary

Introduction

Tissue wounding induces an immediate response necessary to restore epithelial barriers and stop pathogen entry. Controlling macrophage function appears as an attractive approach to promote tissue repair in patients with trauma or degenerative disorders These different functions played by macrophages during wound healing can be explained by the remarkable plasticity of macrophages that are able to acquire different phenotypes based on the environmental cues that have been received. During the resolution phase, changing environmental cues trigger macrophages to shift to an anti-inflammatory M2-like phenotype and secrete anti-inflammatory cytokines like TGF-b1 and IL-10 These M2-like macrophages play an important role in tissue repair including re-epithelization, re-vascularization and fibroblast regeneration as well as in the resolution of inflammation [4, 12, 14, 15]. This simplistic view of macrophage polarization has been challenged by the discovery that macrophage phenotypes encompass a larger array of activation states and profiles, beyond M1 and M2, in vitro and in vivo, suggesting that more than 2 macrophage phenotypes are involved in the wound healing process [18,19,20]

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