The G-protein coupled receptor OXER1 is a tissue redox sensor essential for intestinal epithelial barrier integrity

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The G-protein coupled receptor OXER1 and its ligand 5-KETE are essential tissue redox sensors that protect intestinal epithelial barrier integrity by inducing DNA-protective enzymes.

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AI-generated deep summary by claude@2026-07, 2026-07-14 · read from full text

The paper investigates how mucosal cells sense and adapt to reactive oxygen species (ROS) to maintain barrier integrity, focusing on the redox-sensitive oxoeicosanoid 5-KETE and its receptor OXER1. Using live zebrafish larvae and cultured human cells, the authors report that loss of the OXER1 ortholog (Hcar1-4) leads to intestinal barrier defects and increased baseline inflammation. They find that OXER1 signaling protects against oxidative nucleotide damage by inducing DNA-protective Nudix hydrolases. The main caveat is that the work is confined to intestinal epithelial contexts in zebrafish and cultured human cells rather than broader tissue types. The paper does not explicitly discuss endometriosis or adenomyosis; it was included in the corpus via a keyword match in the upstream search index.

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Abstract

Generation of reactive oxygen species is an important part of the innate immune response. Generating microbicidal levels of reactive oxygen species (ROS) requires adaptation of mucosal barriers. High tolerance of ROS provides improved innate immune defenses against pathogens, whereas low tolerance renders host cells prone to chronic toxicity and mutagenesis, which can promote inflammation (e.g., in asthma and Crohn’s disease) and cancerogenesis. The mechanisms that sense and mediate host tolerance to ROS are little understood. In this study, we discover an unexpected role for the redox-sensitive, chemokine-like lipid 5-oxo-eicosatetraenoic acid (5-KETE) in redox adaptation. 5-KETE is known to attract leukocytes to damaged/infected mucosal barriers by signaling through its receptor, OXER1. Suggestive of a distinct non-immune function, we here report that the loss of the OXER1 ortholog Hcar1-4 causes barrier defects and baseline inflammation in the intestine of live zebrafish larvae. In zebrafish and cultured human cells, OXER1 signaling protects against oxidative nucleotide lesions by inducing DNA-protective Nudix hydrolases. Our data reveal the oxoeicosanoid pathway as a conserved ROS resilience mechanism that fortifies pathogen-exposed mucosal linings against increased oxidative stress in vivo .
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Abstract Generation of reactive oxygen species is an important part of the innate immune response. Generating microbicidal levels of reactive oxygen species (ROS) requires adaptation of mucosal barriers. High tolerance of ROS provides improved innate immune defenses against pathogens, whereas low tolerance renders host cells prone to chronic toxicity and mutagenesis, which can promote inflammation (e.g., in asthma and Crohn’s disease) and cancerogenesis. The mechanisms that sense and mediate host tolerance to ROS are little understood. In this study, we discover an unexpected role for the redox-sensitive, chemokine-like lipid 5-oxo-eicosatetraenoic acid (5-KETE) in redox adaptation. 5-KETE is known to attract leukocytes to damaged/infected mucosal barriers by signaling through its receptor, OXER1. Suggestive of a distinct non-immune function, we here report that the loss of the OXER1 ortholog Hcar1-4 causes barrier defects and baseline inflammation in the intestine of live zebrafish larvae. In zebrafish and cultured human cells, OXER1 signaling protects against oxidative nucleotide lesions by inducing DNA-protective Nudix hydrolases. Our data reveal the oxoeicosanoid pathway as a conserved ROS resilience mechanism that fortifies pathogen-exposed mucosal linings against increased oxidative stress in vivo. Competing Interest Statement The authors have declared no competing interest.

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europepmc
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License: CC-BY-4.0