Abstract
Background: Hepatic macrophages play an indispensable role in liver pathophysiology, serving as key orchestrators of both liver injury and repair processes. ATG16L1 (autophagy-related 16 like 1) has emerged as a novel and critical autophagy marker. In macrophages, ATG16L1 assumes a particularly crucial role. The current understanding of how macrophage ATG16L1 regulates liver inflammation in the context of liver fibrosis is unclear. Methods: This study included clinical patient samples of liver fibrosis and established a murine model with myeloid-specific Atg16l1 knockout, creating a mouse model of liver fibrosis. Employing RNA sequencing, we sought to elucidate the mechanisms of macrophage ATG16L1 in liver fibrosis by identifying critical signaling pathways. To assess the influence of macrophage ATG16L1 on hepatocyte apoptosis and hepatic stellate cell (HSC) activation, we constructed a dedicated culture system. Ultimately, the introduction of mice with myeloid-specific Atg16l1 knock-in substantiated the protective role of myeloid-specific Atg16l1 against inflammatory signaling, hepatocyte apoptosis, and activation of HSCs. Results: An upregulation of the ATG16L1 signal was observed in the liver tissues of patients with liver fibrosis and in fibrotic mice, predominantly localized to hepatic macrophages. In Atg16l1 (ΔMφ) mice afflicted with liver fibrosis, we detected exacerbated liver damage, evidenced by heightened inflammatory signal expression, increased hepatocyte apoptosis, and enhanced activation of HSCs. The absence of macrophage Atg16l1 was found to result in elevated TNF receptor-associated factor 1 (TRAF1) signaling, triggering inflammatory activation, intensifying hepatocyte apoptosis, and facilitating HSC activation through the transforming growth factor beta 1 (TGF-β1) signaling. The detrimental effects of macrophage Atg16l1 depletion were demonstrated to be mitigated upon Atg16l1 reintroduction. Conclusions: This research delved into the mechanisms by which the macrophage ATG16L1 signal influences inflammatory signaling, hepatocyte apoptosis, and activation of HSCs in liver fibrosis. Consequently, it offers theoretical substantiation and an experimental groundwork for the identification of biological targets for therapeutic intervention in liver fibrosis.