Acute neuroinflammation rapidly activates brain immune responses, but its lasting effects on microglia are unclear. Using systemic LPS administration and LCMV-Armstrong infection, we found that blood-brain barrier disruption and cytokine shifts resolved within 30 days, yet microglial recovery was incomplete-marked by persistent numerical loss and an IFN-γ-low phenotype in the LPS model and reduced relative abundance in the LCMV model. Single-cell RNA sequencing revealed sustained transcriptional alterations, including disease-associated microglia (DAM) features and a distinct recovery-biased population. These acute signatures overlapped with profiles from Alzheimer's model mice and were enriched in human microglia from multiple sclerosis, Alzheimer's disease, and other neuroinflammatory conditions. Although our observation period was shorter than the chronic course of these diseases, the persistence of disease-like microglial states suggests that transient inflammation can prime the brain for long-term vulnerability. Targeting this primed state may offer new strategies to prevent or mitigate neurodegenerative pathology.

Studies over the last 2 decades have identified IL-17 and IL-21 as key cytokines in the modulation of a wide range of immune responses. IL-17 serves as a critical defender against bacterial and fungal pathogens, while maintaining symbiotic relationships with commensal microbiota. However, alterations in its levels can lead to chronic inflammation and autoimmunity. IL-21, on the other hand, bridges the adaptive and innate immune responses, and its imbalance is implicated in autoimmune diseases and cancer, highlighting its important role in both health and disease. Delving into the intricacies of these cytokines not only opens new avenues for understanding the immune system, but also promises innovative advances in the development of therapeutic strategies for numerous diseases. In this review, we will discuss an updated view of the immunobiology and therapeutic potential of IL-17 and IL-21.

Acute neuroinflammation rapidly activates brain immune responses, but its lasting effects on microglia are unclear. Using systemic LPS administration and LCMV-Armstrong infection, we found that blood-brain barrier disruption and cytokine shifts resolved within 30 days, yet microglial recovery was incomplete-marked by persistent numerical loss and an IFN-γ-low phenotype in the LPS model and reduced relative abundance in the LCMV model. Single-cell RNA sequencing revealed sustained transcriptional alterations, including disease-associated microglia (DAM) features and a distinct recovery-biased population. These acute signatures overlapped with profiles from Alzheimer's model mice and were enriched in human microglia from multiple sclerosis, Alzheimer's disease, and other neuroinflammatory conditions. Although our observation period was shorter than the chronic course of these diseases, the persistence of disease-like microglial states suggests that transient inflammation can prime the brain for long-term vulnerability. Targeting this primed state may offer new strategies to prevent or mitigate neurodegenerative pathology.

Studies over the last 2 decades have identified IL-17 and IL-21 as key cytokines in the modulation of a wide range of immune responses. IL-17 serves as a critical defender against bacterial and fungal pathogens, while maintaining symbiotic relationships with commensal microbiota. However, alterations in its levels can lead to chronic inflammation and autoimmunity. IL-21, on the other hand, bridges the adaptive and innate immune responses, and its imbalance is implicated in autoimmune diseases and cancer, highlighting its important role in both health and disease. Delving into the intricacies of these cytokines not only opens new avenues for understanding the immune system, but also promises innovative advances in the development of therapeutic strategies for numerous diseases. In this review, we will discuss an updated view of the immunobiology and therapeutic potential of IL-17 and IL-21.

T cell exhaustion, which is observed in various chronic infections and malignancies, is characterized by elevated expression of multiple inhibitory receptors, impaired effector functions, decreased proliferation, and reduced cytokine production. Notably, while adoptive T cell therapies, such as chimeric antigen receptor (CAR)-T therapy, have shown promise in treating cancer and other diseases, the efficacy of these therapies is often compromised by T cell exhaustion. It is imperative, therefore, to understand the mechanisms underlying this exhaustion to promote advances in T cell-related therapies. Here, we divided exhausted T cells into three distinct subsets according to their developmental and functional profiles: stem-like progenitor cells, intermediately exhausted cells, and terminally exhausted cells. These subsets are carefully regulated by synergistic mechanisms that involve transcriptional and epigenetic modulators. Key transcription factors, such as TCF1, BACH2, and TOX, are crucial for defining and sustaining exhaustion phenotypes. Concurrently, epigenetic regulators, such as TET2 and DNMT3A, shape the chromatin dynamics that direct T cell fate. The interplay of these molecular drivers has recently been highlighted in CAR-T research, revealing promising therapeutic directions. Thus, a profound understanding of exhausted T cell hierarchies and their molecular complexities may reveal innovative and improved tumor treatment strategies.

<div>Abstract<p>PD-1–based cancer immunotherapy is a successful example of immune checkpoint blockade that provides long-term durable therapeutic effects in patients with cancer across a wide spectrum of cancer types. Accumulating evidence suggests that anti-PD-1 therapy enhances antitumor immunity by reversing the function of exhausted T cells in the tumor environment. However, the responsiveness rate of patients with cancer to anti-PD-1 therapy remains low, providing an urgent need for optimization and improvement. In this study, we designed an anti-PD-1–resistant mouse tumor model and showed that unresponsiveness to anti-PD-1 is associated with a gradual increase in CD8 T-cell exhaustion. We also found that invariant natural killer T cell stimulation by the synthetic ligand α-galactosylceramide (αGC) can enhance the antitumor effect in anti-PD-1–resistant tumors by restoring the effector function of tumor antigen–specific exhausted CD8 T cells. IL2 and IL12 were among the cytokines produced by αGC stimulation critical for reinvigorating exhausted CD8 T cells in tumor-bearing mice and patients with cancer. Furthermore, we observed a synergistic increase in the antitumor effect between αGC-loaded antigen-presenting cells and PD-1 blockade in a therapeutic murine tumor model. Our study suggests NKT cell stimulation as a promising therapeutic strategy for the treatment of patients with anti-PD-1–resistant cancer.</p><p><b>Significance:</b> These findings provide mechanistic insights into the application of NKT cell stimulation as a potent adjuvant for immunotherapy against advanced cancer. <i>Cancer Res; 78(18); 5315–26. ©2018 AACR</i>.</p></div>

<p>Supplementary Figures</p>

plasma treatment, the SPSM supports long-term spheroid culture (>14 days) with high viability (>95%) and minimal handling. Its utility is validated in cytotoxicity assays using doxorubicin (DOX) and chimeric antigen receptor (CAR) T cells, where label-free efficacy assessment based on spheroid size correlates with fluorescence staining in commercial ultralow attachment (ULA) plates. This platform provides a robust and quantitative approach for evaluating drug and immune cell therapies, readily adaptable for broader immuno-oncology investigations.