Intervertebral disc degeneration (IDD) is a degenerative spinal condition characterized by disc structural damage, narrowing of joint spaces, and nerve root compression, significantly reducing patients' quality of life. To address this challenge, a novel therapeutic strategy was developed using cellulose supramolecular hydrogel as a carrier to deliver IL4I1-modified MΦ membrane biomimetic nanoparticles (CHG@IL4I1-MNPs) to target tissues. This hydrogel exhibits excellent biocompatibility and mechanical properties while enabling sustained drug release in the degenerative disc microenvironment, enhancing therapeutic outcomes. CHG@IL4I1-MNPs effectively regulate MΦ polarization by promoting M2 MΦ activation, thereby improving immune microenvironment balance. Animal studies demonstrated that CHG@IL4I1-MNPs alleviated symptoms of IDD, reduced inflammation, and supported tissue repair, highlighting its potential to reduce reliance on long-term medication and improve quality of life. The strategy uniquely combines nanoparticle technology with immunomodulation, achieving precise targeting of MΦs. Beyond IDD, this approach offers potential applications in other immune-related diseases, providing a versatile platform for nanomedicine. This study introduces an innovative method to treat IDD and advances the integration of immunotherapy and nanotechnology, offering both clinical benefits and new directions for future research. These findings hold strong potential for improving patient outcomes and expanding treatment options for related diseases.
© 2025. The Author(s).

Background: Inducing immunogenic cell death (ICD) is a promising strategy to enhance immune responses for immune checkpoint blockade (ICB) therapy, but the lack of a simple and effective platform to integrate ICD and ICB therapy limits their clinical application. Methods: Here, we developed programmed cell death protein 1 (PD1)-overexpressing genetically engineered nanovesicles (NVs)-coated curcumin (Cur)-loaded poly (lactic-co-poly-polyglycolic acid) nanoparticles (PD1@Cur-PLGA) to integrate ICD and ICB therapy for enhancing tumor immunotherapy. Results: Genetically engineered NVs greatly enhanced the tumor targeting of nanoparticles, and the PD1 on NVs dramatically blocked the PD1/PDL1 signaling pathway and stimulated antitumor immune responses. Meanwhile, the delivered Cur successfully induced tumor cell apoptosis and activated ICD by inhibiting NF-κB phosphorylation and Bcl-2 protein expression and activating caspase and Bax apoptotic signaling. By synergizing the ICD effect of Cur and the PD1/PDL1 axis blocking function of genetically engineered NVs, the PD1@Cur-PLGA enhanced the intratumoral infiltration rate of mature dendritic cells and CD8+ T cells in tumor tissues, resulting in significantly inhibiting tumor growth in breast and prostate tumor-bearing mouse models. Conclusion: This synergistic ICD and ICB therapy based on genetically engineered NVs provides a low-cost, safe, and effective strategy to enhance cancer immunotherapy.
© The author(s).

SMAD4 deficiency in colorectal cancer (CRC) is highly correlated with liver metastasis and high mortality, yet there are few effective precision therapies available. Here, we show that CCR1+-granulocytic myeloid-derived suppressor cells (G-MDSCs) are highly infiltrated in SMAD4-deficient CRC via CCL15/CCR1 and CCL9/CCR1 axis in clinical specimens and mouse models, respectively. The excessive TGF-β, secreted by tumor-infiltrated CCR1+-G-MDSCs, suppresses the immune response of cytotoxic T lymphocytes (CTLs), thus facilitating metastasis. Hereby, we develop engineered nanovesicles displaying CCR1 and TGFBR2 molecules (C/T-NVs) to chemotactically target the tumor driven by CCL9/CCR1 axis and trap TGF-β through TGF-β-TGFBR2 specific binding. Chemotactic C/T-NVs counteract CCR1+-G-MDSC infiltration through competitive responding CCL9/CCR1 axis. C/T-NVs-induced intratumoral TGF-β exhaustion alleviates the TGF-β-suppressed immune response of CTLs. Collectively, C/T-NVs attenuate liver metastasis of SMAD4-deficient CRC. In further exploration, high expression of programmed cell death ligand-1 (PD-L1) is observed in clinical specimens of SMAD4-deficient CRC. Combining C/T-NVs with anti-PD-L1 antibody (aPD-L1) induces tertiary lymphoid structure formation with sustained activation of CTLs, CXCL13+-CD4+ T, CXCR5+-CD20+ B cells, and enhanced secretion of cytotoxic cytokine interleukin-21 and IFN-γ around tumors, thus eradicating metastatic foci. Our strategy elicits pleiotropic antimetastatic immunity, paving the way for nanovesicle-mediated precision immunotherapy in SMAD4-deficient CRC.
© 2024 The Authors.

The tumor microenvironment (TME) presents differential selective pressure (DSP) that favors the growth of cancer cells, and monovalent therapy is often inadequate in reversing the cancer cell dominance in the TME. In this work, we introduce bacteria as a foreign species to the TME and explore combinatorial treatment strategies to alter DSP for tumor eradication. We show that cancer-selective chemotherapeutic agents and fasting can provide a strong selection pressure against tumor growth in the presence of bacteria. Moreover, we show that an immunogenic drug (oxaliplatin), but not a non-immunogenic one (5-FU), synergizes with the bacteria to activate both the innate and adaptive immunity in the TME, resulting in complete tumor remission and a sustained anti-tumor immunological memory in mice. The combination of oxaliplatin and bacteria greatly enhances the co-stimulatory and antigen-presenting molecules on antigen-presenting cells, which in turn bridge the cytotoxic T cells for cancer-cell killing. Our findings indicate that rational combination of bacterial therapy and immunogenic chemotherapy can promote anticancer immunity against the immunosuppressive TME.
© 2024. The Author(s).

Inflammatory bowel disease (IBD) is a chronic immune-mediated disorder affecting millions worldwide. Due to the complexity of its pathogenesis, the treatment options for IBD are limited. This study focuses on ELF4, a member of the ETS transcription factor family, as a target to elucidate its role in IBD and investigate its mechanism of action in alleviating IBD symptoms by activating IL1RN transcription to suppress the activity of inflammatory TH17 cells.
Using the GEO database, this study examined LPS-induced intestinal inflammatory genes and their regulation mechanisms. We examined the colon length of LPS-treated mice and derived the Disease Activity Index (DAI). H&E staining, ELISA, and flow cytometry were used to detect mice colon tissue damage, inflammatory factor levels in mouse serum, mouse macrophage types and inflammatory TH17 cell activity. RT-qPCR and Western blot detected ELF4, IL1RN, M1, and M2 polarization markers. In Vitro, using dual-luciferase and ChIP assays, we tested mouse bone marrow-derived macrophages (BMDMs) and mouse intestinal epithelial cells for IL1RN promoter activity and ELF4 enrichment.
Bioinformatics showed that LPS-induced colitis animals have reduced ELF4 expression in their colon tissue. In vivo tests confirmed reduced ELF4 expression in mice with LPS-induced colitis. ELF4 overexpression reduced mouse intestinal inflammation. ELF4 activated IL1RN transcription in bioinformatics and in vitro tests. ELF4 promoted IL1RN transcription and macrophage M2 polarization to limit intestinal epithelial cell death and inflammation and reduce mouse intestinal inflammation in vitro. ELF4 also reduced the Th17/Treg ratio by increasing IL1RN transcription.
ELF4 activates IL1RN transcription, suppresses inflammatory TH17 cells, and induces macrophage M2 polarization to treat IBD.
Copyright © 2023 Cao, Chen, Peng, Cheng, Xie, Hou, Chen, Ye, Li, Wang, Ren, Xiong, Geng and Gong.