DOI: 10.1093/jimmun/vkag151 ISSN: 0022-1767

ER stress amplifies inflammation via a dual mechanism involving IκBζ–XBP1s synergism and Regnase-1 degradation

Yuri Nakaminami, Lerdluck Ruengsinpinya, Riko Sakihara, Yoshifumi Takahata, Kenji Hata, Takao Iwawaki, Riko Nishimura, Tomohiko Murakami

Abstract

Inflammatory diseases arise from complex interactions between immune signaling and cellular stress. Although endoplasmic reticulum (ER) stress is a key modulator of immunity, the mechanisms by which it promotes inflammatory pathology remain incompletely understood. Notably, ER stress–induced NF-κB activation alone is insufficient to account for robust IL-6 production, thus suggesting the involvement of additional regulators. Using bone marrow–derived macrophages and sepsis model mice, we identified the inducible transcription factor IκBζ as a critical mediator of this response, with ER stress synergizing with TLR signaling to markedly upregulate IκBζ. Mechanistically, ER stress triggered calcium-dependent signaling that led to IκB kinase–mediated degradation of the RNase Regnase-1, likely stabilizing Nfkbiz mRNA and promoting the accumulation of IκBζ, which was found to cooperate with the ER stress factor XBP1s to drive transcription of selected secondary-response genes, particularly Il6 and Nos2. Importantly, this synergy was required for excessive IL-6 production in septic mice, highlighting a gene-specific amplification pathway. Together, these findings identify a dual mechanism in which transcriptional synergy between IκBζ and XBP1s is coupled to posttranscriptional mRNA stabilization via Regnase-1 degradation, thereby linking proteotoxic stress to hyperinflammatory responses. Our results establish ER stress–mediated IκBζ accumulation as a key driver of inflammatory pathogenesis and a potential therapeutic target in ER stress–associated inflammatory disorders.

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