Activation of the NLRP3 inflammasome causes extensive disturbance of cellular homeostasis, with Golgi disruption, mitochondrial dysfunction, and changes in intracellular ion concentration occurring rapidly upon stimulation. Given this, it would seem near certain that these changes might also globally affect cellular signaling pathways, yet few, if any, studies have explored this possibility. Here, we combine genomics and phosphoproteomics to identify inhibition of the ERK1/2 MAP kinase signaling cascade upon inflammasome stimulation. This loss of ERK1/2 activity results in rapid inactivation of the mRNA decay-promoting protein tristetraprolin (TTP), with loss of TTP promoting subsequent increased release of cytokines upon pyroptosis. Further, we observe significantly increased levels of TTP expression in patients with inflammatory bowel disease, a disease for which altered cytokine expression is a key driver of pathogenesis. Inflammasome activation thus rapidly inactivates a pathway designed to suppress cytokine release, potentially exacerbating hyperinflammatory states, including those involved in autoinflammatory disease.
Keywords: CP: Immunology; CP: Molecular biology; MAP kinases; cytokines; inflammasome; mitochondria; phosphatase; post-translational modifications; signaling cascades.
Copyright © 2025 The Author(s). Published by Elsevier Inc. All rights reserved.