| Literature DB >> 30293776 |
Jorge Domínguez-Andrés1, Boris Novakovic2, Yang Li3, Brendon P Scicluna4, Mark S Gresnigt5, Rob J W Arts6, Marije Oosting6, Simone J C F M Moorlag6, Laszlo A Groh6, Jelle Zwaag7, Rebecca M Koch7, Rob Ter Horst6, Leo A B Joosten6, Cisca Wijmenga3, Alessandro Michelucci8, Tom van der Poll4, Matthijs Kox7, Peter Pickkers7, Vinod Kumar9, Henk Stunnenberg2, Mihai G Netea10.
Abstract
Sepsis involves simultaneous hyperactivation of the immune system and immune paralysis, leading to both organ dysfunction and increased susceptibility to secondary infections. Acute activation of myeloid cells induced itaconate synthesis, which subsequently mediated innate immune tolerance in human monocytes. In contrast, induction of trained immunity by β-glucan counteracted tolerance induced in a model of human endotoxemia by inhibiting the expression of immune-responsive gene 1 (IRG1), the enzyme that controls itaconate synthesis. β-Glucan also increased the expression of succinate dehydrogenase (SDH), contributing to the integrity of the TCA cycle and leading to an enhanced innate immune response after secondary stimulation. The role of itaconate was further validated by IRG1 and SDH polymorphisms that modulate induction of tolerance and trained immunity in human monocytes. These data demonstrate the importance of the IRG1-itaconate-SDH axis in the development of immune tolerance and training and highlight the potential of β-glucan-induced trained immunity to revert immunoparalysis.Entities:
Keywords: LPS; epigenetics; immunoparalysis; itaconate; metabolism; monocytes; sepsis; succinate; tolerance; trained immunity
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Year: 2018 PMID: 30293776 DOI: 10.1016/j.cmet.2018.09.003
Source DB: PubMed Journal: Cell Metab ISSN: 1550-4131 Impact factor: 27.287