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CCL28 调节黏膜病原体感染期间的中性粒细胞反应。

CCL28 modulates neutrophil responses during infection with mucosal pathogens.

机构信息

Division of Host-Microbe Systems & Therapeutics, Department of Pediatrics, University of California, San Diego, La Jolla, United States.

Department of Microbiology and Molecular Genetics, University of California Irvine, Irvine, United States.

出版信息

Elife. 2024 Aug 28;13:e78206. doi: 10.7554/eLife.78206.

DOI:10.7554/eLife.78206
PMID:39193987
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11444682/
Abstract

The chemokine CCL28 is highly expressed in mucosal tissues, but its role during infection is not well understood. Here, we show that CCL28 promotes neutrophil accumulation in the gut of mice infected with and in the lung of mice infected with . Neutrophils isolated from the infected mucosa expressed the CCL28 receptors CCR3 and, to a lesser extent, CCR10, on their surface. The functional consequences of CCL28 deficiency varied between the two infections: mice were highly susceptible to gut infection but highly resistant to otherwise lethal lung infection. In vitro, unstimulated neutrophils harbored pre-formed intracellular CCR3 that was rapidly mobilized to the cell surface following phagocytosis or inflammatory stimuli. Moreover, CCL28 stimulation enhanced neutrophil antimicrobial activity, production of reactive oxygen species, and formation of extracellular traps, all processes largely dependent on CCR3. Consistent with the different outcomes in the two infection models, neutrophil stimulation with CCL28 boosted the killing of but not . CCL28 thus plays a critical role in the immune response to mucosal pathogens by increasing neutrophil accumulation and activation, which can enhance pathogen clearance but also exacerbate disease depending on the mucosal site and the infectious agent.

摘要

趋化因子 CCL28 在黏膜组织中高度表达,但它在感染过程中的作用尚不清楚。在这里,我们表明 CCL28 促进了 感染的小鼠肠道和 感染的小鼠肺部中性粒细胞的积累。从受感染的黏膜中分离出的中性粒细胞在其表面表达 CCL28 受体 CCR3 和在较小程度上表达 CCR10。CCL28 缺乏在两种感染中的功能后果不同:CCL28 缺陷小鼠对 肠道感染高度易感,但对其他致命的 肺部感染高度抵抗。在体外,未受刺激的中性粒细胞含有预先形成的细胞内 CCR3,在吞噬作用或炎症刺激后迅速向细胞表面转移。此外,CCL28 刺激增强了中性粒细胞的抗菌活性、活性氧物质的产生和细胞外陷阱的形成,所有这些过程在很大程度上都依赖于 CCR3。与两种感染模型的不同结果一致,CCL28 刺激中性粒细胞增加了对 的杀伤,但不能增加对 的杀伤。因此,CCL28 通过增加中性粒细胞的积累和激活,在针对黏膜病原体的免疫反应中发挥关键作用,这可以增强病原体的清除,但也取决于黏膜部位和感染因子,从而加重疾病。

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3
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