Alveolar macrophages (AMs) reside in the lower airways and play a crucial role in lung health and response to sterile inflammation and infections. AMs possess remarkable adaptability to different environmental challenges that can persist through their memory capacity (trained immunity). β-Glucan has been characterized as a potent inducer of central trained immunity by reprogramming haematopoietic stem cells in the bone marrow. In the present study, we show that systemic administration of β-glucan in mice induces peripheral trained immunity by reprogramming AMs in the lungs, in a Dectin1-independent manner. We furthermore demonstrate that AM reprogramming at both the transcriptional and metabolic levels exacerbate lung injury following bacterial (lipopolysaccharide) or viral (polyI:C) challenges via a neutrophil/IFN-γ-dependent manner. These findings identify an additional facet of β-glucan in trained immunity involving AM reprogramming and shed light on the potential detrimental effects of trained immunity.
© 2024, Prevel et al.

Chronic hepatitis B virus (HBV) infection is marked by dysfunctional HBV-specific CD8+ T cells, and restoring their effector activity is a major therapeutic goal. Here, we generated HBV-specific CD4+ T cell receptor transgenic mice to show that CD4+ effector T cells can prevent and reverse the CD8⁺ T cell dysfunction induced by hepatocellular priming. This rescue enhances antiviral CD8+ T cell function and suppresses viral replication. CD4+ T cell help occurs directly within the liver, independent of secondary lymphoid organs, and requires local antigen recognition. Kupffer cells, rather than dendritic cells, are the critical antigen-presenting platform. CD4+ T cells license Kupffer cells via CD40-CD40L interactions, triggering interleukin (IL)-12 and IL-27 production. IL-12 expands the CD4+ T cell pool, while IL-27 is essential for CD8+ T cell rescue. Exogenous IL-27 similarly restores HBV-specific CD8+ T cell function in mice and in T cells isolated from chronically infected patients. These findings identify IL-27 as a tractable immunotherapeutic target in chronic HBV infection.
© 2025. The Author(s).

Natural killer (NK) cells can control metastasis through cytotoxicity and IFN-γ production independently of T cells in experimental metastasis mouse models. The inverse correlation between NK activity and metastasis incidence supports a critical role for NK cells in human metastatic surveillance. However, autologous NK cell therapy has shown limited benefit in treating patients with metastatic solid tumors. Using a spontaneous metastasis mouse model of MHC-I+ breast cancer, we found that transfer of IL-15/IL-12-conditioned syngeneic NK cells after primary tumor resection promoted long-term survival of mice with low metastatic burden and induced a tumor-specific protective T cell response that is essential for the therapeutic effect. Furthermore, NK cell transfer augments activation of conventional dendritic cells (cDCs), Foxp3-CD4+ T cells and stem cell-like CD8+ T cells in metastatic lungs, to which IFN-γ of the transferred NK cells contributes significantly. These results imply direct interactions between transferred NK cells and endogenous cDCs to enhance T cell activation. We conducted an investigator-initiated clinical trial of autologous NK cell therapy in six patients with advanced cancer and observed that the NK cell therapy was safe and showed signs of effectiveness. These findings indicate that autologous NK cell therapy is effective in treating established low burden metastases of MHC-I+ tumor cells by activating the cDC-T cell axis at metastatic sites.
© 2024, Huang, Lai, Liao et al.

A combination of hematopoietic stem cell (HSC)- and endothelial cell (EC)-lineage-tracing mouse models enables us to determine blood cell origins. We present a protocol to induce cell labeling in vivo and to trace labeled hematopoietic cells to segregate their origins. We describe the steps for harvesting various hematopoietic tissues, antibody staining, and analyzing the Tomato+ percentages within each immune cell population. We also show how to estimate HSC- and EC-derived percentages of the target cell populations. For complete details on the use and execution of this protocol, please refer to Kobayashi et al.1.
Copyright © 2024 The Author(s). Published by Elsevier Inc. All rights reserved.

To increase antibody affinity against pathogens, positively selected GC-B cells initiate cell division in the light zone (LZ) of germinal centers (GCs). Among these, higher-affinity clones migrate to the dark zone (DZ) and vigorously proliferate by utilizing energy provided by oxidative phosphorylation (OXPHOS). However, it remains unknown how positively selected GC-B cells adapt their metabolism for cell division in the glycolysis-dominant, cell cycle arrest-inducing, hypoxic LZ microenvironment. Here, we show that microRNA (miR)-155 mediates metabolic reprogramming during positive selection to protect high-affinity clones. Mechanistically, miR-155 regulates H3K36me2 levels in hypoxic conditions by directly repressing the histone lysine demethylase, Kdm2a, whose expression increases in response to hypoxia. The miR-155-Kdm2a interaction is crucial for enhancing OXPHOS through optimizing the expression of vital nuclear mitochondrial genes under hypoxia, thereby preventing excessive production of reactive oxygen species and subsequent apoptosis. Thus, miR-155-mediated epigenetic regulation promotes mitochondrial fitness in high-affinity GC-B cells, ensuring their expansion and consequently affinity maturation.
© 2024. The Author(s).