UV radiation recruits CD4+GATA3+ and CD8+GATA3+ T cells while altering the lipid microenvironment following inflammatory resolution in human skin in vivo

UV radiation recruits CD4+GATA3+ and CD8+GATA3+ T cells while altering the lipid microenvironment following inflammatory resolution in human skin in vivo

Abstract Objectives Solar ultraviolet radiation (UVR) has major adverse effects on human health. While the mechanisms responsible for induction of UVR‐induced inflammation are well‐documented, the mediation of its resolution and longer‐term adaptive homeostasis is unknown. Therefore, we examined the...

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Main Authors: Nathan J Hawkshaw, Suzanne M Pilkington, Sharon A Murphy, Norah Al‐Gazaq, Mark D Farrar, Rachel EB Watson, Anna Nicolaou, Lesley E Rhodes
Format: Article
Language:English
Published: Wiley 2020-01-01
Series:Clinical & Translational Immunology
Subjects:
inflammation
immunosuppression
lipidomics
resolution
T cells
ultraviolet radiation
Online Access:https://doi.org/10.1002/cti2.1104
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record_format Article
collection DOAJ
language English
format Article
sources DOAJ
author Nathan J Hawkshaw
Suzanne M Pilkington
Sharon A Murphy
Norah Al‐Gazaq
Mark D Farrar
Rachel EB Watson
Anna Nicolaou
Lesley E Rhodes
spellingShingle Nathan J Hawkshaw
Suzanne M Pilkington
Sharon A Murphy
Norah Al‐Gazaq
Mark D Farrar
Rachel EB Watson
Anna Nicolaou
Lesley E Rhodes
UV radiation recruits CD4+GATA3+ and CD8+GATA3+ T cells while altering the lipid microenvironment following inflammatory resolution in human skin in vivo
Clinical & Translational Immunology
inflammation
immunosuppression
lipidomics
resolution
T cells
ultraviolet radiation
author_facet Nathan J Hawkshaw
Suzanne M Pilkington
Sharon A Murphy
Norah Al‐Gazaq
Mark D Farrar
Rachel EB Watson
Anna Nicolaou
Lesley E Rhodes
author_sort Nathan J Hawkshaw
title UV radiation recruits CD4+GATA3+ and CD8+GATA3+ T cells while altering the lipid microenvironment following inflammatory resolution in human skin in vivo
title_short UV radiation recruits CD4+GATA3+ and CD8+GATA3+ T cells while altering the lipid microenvironment following inflammatory resolution in human skin in vivo
title_full UV radiation recruits CD4+GATA3+ and CD8+GATA3+ T cells while altering the lipid microenvironment following inflammatory resolution in human skin in vivo
title_fullStr UV radiation recruits CD4+GATA3+ and CD8+GATA3+ T cells while altering the lipid microenvironment following inflammatory resolution in human skin in vivo
title_full_unstemmed UV radiation recruits CD4+GATA3+ and CD8+GATA3+ T cells while altering the lipid microenvironment following inflammatory resolution in human skin in vivo
title_sort uv radiation recruits cd4+gata3+ and cd8+gata3+ t cells while altering the lipid microenvironment following inflammatory resolution in human skin in vivo
publisher Wiley
series Clinical & Translational Immunology
issn 2050-0068
publishDate 2020-01-01
description Abstract Objectives Solar ultraviolet radiation (UVR) has major adverse effects on human health. While the mechanisms responsible for induction of UVR‐induced inflammation are well‐documented, the mediation of its resolution and longer‐term adaptive homeostasis is unknown. Therefore, we examined the skin immune and lipid profile over time following UVR inflammation. Methods To investigate the self‐resolving events of UVR inflammation in vivo, human skin was exposed to a single pro‐inflammatory dose of UVR. Skin biopsies and suction blister fluid were taken at intervals up to 2 weeks post‐UVR. The immune infiltrate was quantified by immunohistochemistry, and lipid mediators were profiled by liquid chromatography/mass spectrometry. Results We identified that cellular resolution events including switching of macrophage phenotype apply to human sunburn. However, UVR‐induced inflammation in humans involves a post‐resolution phase that differs from other experimental models. We demonstrate that 2 weeks after the initiating UVR stimulus, there is considerable immune activity with CD8+GATA3+ T cells maintained in human skin. Our results challenge the dogma of CD4+FOXP3+ T cells being the main effector CD4+ T‐cell population following UVR, with CD4+GATA3+ T cells the dominant phenotype. Furthermore, lipid mediators are elevated 14 days post‐UVR, demonstrating the skin lipid microenvironment does not revert to the tissue setting occurring prior to UVR exposure. Conclusion We have identified for the first time that CD4+GATA3+ and CD8+GATA3+ T‐cell subpopulations are recruited to UVR‐inflamed human skin, demonstrating discrepancies between the adaptive UVR response in mice and humans. Future strategies to abrogate UVR effects may target these T‐cell subpopulations and also the persistent alteration of the lipid microenvironment post‐UVR.
topic inflammation
immunosuppression
lipidomics
resolution
T cells
ultraviolet radiation
url https://doi.org/10.1002/cti2.1104
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spelling doaj-143eb1fde9084217b2479f8d099fda852020-11-25T03:07:21ZengWileyClinical & Translational Immunology2050-00682020-01-0194n/an/a10.1002/cti2.1104UV radiation recruits CD4+GATA3+ and CD8+GATA3+ T cells while altering the lipid microenvironment following inflammatory resolution in human skin in vivoNathan J Hawkshaw0Suzanne M Pilkington1Sharon A Murphy2Norah Al‐Gazaq3Mark D Farrar4Rachel EB Watson5Anna Nicolaou6Lesley E Rhodes7Centre for Dermatology Research Division of Musculoskeletal and Dermatological Sciences Faculty of Biology, Medicine and Health School of Biological Sciences Manchester Academic Health Science Centre The University of Manchester and Salford Royal NHS Foundation Trust Manchester UKCentre for Dermatology Research Division of Musculoskeletal and Dermatological Sciences Faculty of Biology, Medicine and Health School of Biological Sciences Manchester Academic Health Science Centre The University of Manchester and Salford Royal NHS Foundation Trust Manchester UKLaboratory for Lipidomics and Lipid Biology Division of Pharmacy and Optometry Faculty of Biology Medicine and Health School of Health Sciences The University of Manchester Manchester UKLaboratory for Lipidomics and Lipid Biology Division of Pharmacy and Optometry Faculty of Biology Medicine and Health School of Health Sciences The University of Manchester Manchester UKCentre for Dermatology Research Division of Musculoskeletal and Dermatological Sciences Faculty of Biology, Medicine and Health School of Biological Sciences Manchester Academic Health Science Centre The University of Manchester and Salford Royal NHS Foundation Trust Manchester UKCentre for Dermatology Research Division of Musculoskeletal and Dermatological Sciences Faculty of Biology, Medicine and Health School of Biological Sciences Manchester Academic Health Science Centre The University of Manchester and Salford Royal NHS Foundation Trust Manchester UKLaboratory for Lipidomics and Lipid Biology Division of Pharmacy and Optometry Faculty of Biology Medicine and Health School of Health Sciences The University of Manchester Manchester UKCentre for Dermatology Research Division of Musculoskeletal and Dermatological Sciences Faculty of Biology, Medicine and Health School of Biological Sciences Manchester Academic Health Science Centre The University of Manchester and Salford Royal NHS Foundation Trust Manchester UKAbstract Objectives Solar ultraviolet radiation (UVR) has major adverse effects on human health. While the mechanisms responsible for induction of UVR‐induced inflammation are well‐documented, the mediation of its resolution and longer‐term adaptive homeostasis is unknown. Therefore, we examined the skin immune and lipid profile over time following UVR inflammation. Methods To investigate the self‐resolving events of UVR inflammation in vivo, human skin was exposed to a single pro‐inflammatory dose of UVR. Skin biopsies and suction blister fluid were taken at intervals up to 2 weeks post‐UVR. The immune infiltrate was quantified by immunohistochemistry, and lipid mediators were profiled by liquid chromatography/mass spectrometry. Results We identified that cellular resolution events including switching of macrophage phenotype apply to human sunburn. However, UVR‐induced inflammation in humans involves a post‐resolution phase that differs from other experimental models. We demonstrate that 2 weeks after the initiating UVR stimulus, there is considerable immune activity with CD8+GATA3+ T cells maintained in human skin. Our results challenge the dogma of CD4+FOXP3+ T cells being the main effector CD4+ T‐cell population following UVR, with CD4+GATA3+ T cells the dominant phenotype. Furthermore, lipid mediators are elevated 14 days post‐UVR, demonstrating the skin lipid microenvironment does not revert to the tissue setting occurring prior to UVR exposure. Conclusion We have identified for the first time that CD4+GATA3+ and CD8+GATA3+ T‐cell subpopulations are recruited to UVR‐inflamed human skin, demonstrating discrepancies between the adaptive UVR response in mice and humans. Future strategies to abrogate UVR effects may target these T‐cell subpopulations and also the persistent alteration of the lipid microenvironment post‐UVR.https://doi.org/10.1002/cti2.1104inflammationimmunosuppressionlipidomicsresolutionT cellsultraviolet radiation

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