Andrew Sullivan1, Eryi Wang1, John Farrell1, Paul Whitaker2, Lee Faulkner1, Daniel Peckham2, B Kevin Park1, Dean J Naisbitt3. 1. MRC Centre for Drug Safety Science, Department of Molecular and Clinical Pharmacology, University of Liverpool, Liverpool, United Kingdom. 2. Regional Adult Cystic Fibrosis Unit, St James's Hospital, Leeds, United Kingdom. 3. MRC Centre for Drug Safety Science, Department of Molecular and Clinical Pharmacology, University of Liverpool, Liverpool, United Kingdom. Electronic address: dnes@liv.ac.uk.
Abstract
BACKGROUND: β-Lactam hypersensitivity has been classified according to the phenotype and function of drug-specific T cells. However, new T-cell subsets have not been considered. OBJECTIVE: The objective of this study was to use piperacillin as a model of β-lactam hypersensitivity to study the nature of the drug-specific T-cell response induced in the blood and skin of hypersensitive patients and healthy volunteers. METHODS: Drug-specific T cells were cloned from blood and inflamed skin, and cellular phenotype and function were explored. Naive T cells from healthy volunteers were primed to piperacillin, cloned, and subjected to the similar analyses. RESULTS: PBMC and T-cell clones (n = 570, 84% CD4+) from blood of piperacillin-hypersensitive patients proliferated and secreted TH1/TH2 cytokines alongside IL-22 after drug stimulation. IL-17A secretion was not detected. Drug-specific clones from inflamed skin (n = 96, 83% CD4+) secreted a similar profile of cytokines but displayed greater cytolytic activity, secreting perforin, granzyme B, and Fas ligand when activated. Blood- and skin-derived clones expressed high levels of skin-homing chemokine receptors and migrated in the presence of the ligands CCL17 and CCL27. Piperacillin-primed naive T cells from healthy volunteers also secreted IFN-γ, IL-13, IL-22, and cytolytic molecules. Aryl hydrocarbon receptor blockade prevented differentiation of the naive T cells into antigen-specific IL-22-secreting cells. CONCLUSION: Together, our results reveal that circulating and skin-resident, antigen-specific, IL-22-secreting T cells are detectable in patients with β-lactam hypersensitivity. Furthermore, differentiation of naive T cells into antigen-specific TH22 cells is dependent on aryl hydrocarbon receptor signaling.
BACKGROUND: β-Lactam hypersensitivity has been classified according to the phenotype and function of drug-specific T cells. However, new T-cell subsets have not been considered. OBJECTIVE: The objective of this study was to use piperacillin as a model of β-lactam hypersensitivity to study the nature of the drug-specific T-cell response induced in the blood and skin of hypersensitive patients and healthy volunteers. METHODS: Drug-specific T cells were cloned from blood and inflamed skin, and cellular phenotype and function were explored. Naive T cells from healthy volunteers were primed to piperacillin, cloned, and subjected to the similar analyses. RESULTS: PBMC and T-cell clones (n = 570, 84% CD4+) from blood of piperacillin-hypersensitive patients proliferated and secreted TH1/TH2 cytokines alongside IL-22 after drug stimulation. IL-17A secretion was not detected. Drug-specific clones from inflamed skin (n = 96, 83% CD4+) secreted a similar profile of cytokines but displayed greater cytolytic activity, secreting perforin, granzyme B, and Fas ligand when activated. Blood- and skin-derived clones expressed high levels of skin-homing chemokine receptors and migrated in the presence of the ligands CCL17 and CCL27. Piperacillin-primed naive T cells from healthy volunteers also secreted IFN-γ, IL-13, IL-22, and cytolytic molecules. Aryl hydrocarbon receptor blockade prevented differentiation of the naive T cells into antigen-specific IL-22-secreting cells. CONCLUSION: Together, our results reveal that circulating and skin-resident, antigen-specific, IL-22-secreting T cells are detectable in patients with β-lactam hypersensitivity. Furthermore, differentiation of naive T cells into antigen-specific TH22 cells is dependent on aryl hydrocarbon receptor signaling.
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