Your search keyword '"fusion vesicles"' showing total 3 results

1. Nanovaccine Showing Potent Immunotherapy to Tumor by Activating Γδ T Cells.

Author

Yang, Zeyu, Li, Liyan, Wei, Chengxiu, Liu, Hong, Qiao, Dongdong, Wen, Zhenfu, Chen, Haolin, Huang, Shanghui, Guo, Rui, Yin, Zhinan, Liu, Lixin, and Chen, Yongming

Subjects

*T cells, *T cell receptors, *MEMBRANE fusion, *CANCER vaccines, *IMMUNOTHERAPY, *MEMBRANE lipids, *SURVIVAL rate

Abstract

Most vaccines are designed to attack tumor cells by activating CD4+/CD8+αβ T cells. Unfortunately, αβ T cells, which only recognize the peptide antigens in the complexes with polymorphic MHCI/II molecules, surrender to the tumor heterogenicity. As another subset of T cells, γδ T cells become salient in antitumor because of their unique immunotherapeutic roles. Herein, a tumor vaccine is developed with multivalent antigens by fusion of tumor cell membranes with lipids and successfully activated γδ T cells via microneedle inoculation. It is certified that the evoked γδ T cells synchronize with αβ T cells revitalizing tumor‐induced immunotolerance. In turn, the tumors of mice are significantly inhibited and their median survival time is prolonged considerably. Moreover, the nanovaccine inhibits tumor recurrence after resection. The therapeutic effects are corroborated with the results from TCRδ−/− mice as well as cytokine expression in tumor. [ABSTRACT FROM AUTHOR]

Published

2023

2. Plant exosomes fused with engineered mesenchymal stem cell‐derived nanovesicles for synergistic therapy of autoimmune skin disorders.

Author

Huang, Rufan, Jia, Bo, Su, Dandan, Li, Manchun, Xu, Zhanxue, He, Chao, Huang, Yisheng, Fan, Hang, Chen, Hongbo, and Cheng, Fang

Subjects

*AUTOIMMUNE diseases, *MESENCHYMAL stem cells, *T helper cells, *REGULATORY T cells, *NANOMEDICINE, *SKIN diseases, *SKIN regeneration, *CHEMOKINE receptors

Abstract

Existing therapeutics for autoimmune diseases remain problematic due to low efficacy, severe side effects, and difficulties to reach target tissues. Herein, we design multifunctional fusion nanovesicles that can target lesions for the treatment of autoimmune skin diseases. The grapefruit‐derived exosome‐like nanovesicles (GEVs) with anti‐inflammatory and antioxidant effects are first encapsulated with CX5461, an immunosuppressant with anti‐proliferative properties to form GEV@CX5461. In order to enhance therapeutic efficiency and safety, GEV@CX5461 are then fused with CCR6+ nanovesicles derived from membranes of engineered gingiva‐derived mesenchymal stem cells (GMSCs). The resulting FV@CX5461 not only maintain the bioactivity of GEVs, CX5461, and GMSC membranes but also home to inflamed tissues rich in chemokine CCL20 through the chemotaxis function of CCR6 on FVs. Moreover, FV@CX5461 reduce the secretion of inflammatory factors, calm down Th17 cell activation, and induce Treg cell infiltration. Finally, impressive therapeutic efficiency in both psoriasis and atopic dermatitis disease models is demonstrated using FV@CX5461 to reshape the unbalanced immune microenvironment. A nanotherapeutic drug delivery strategy is developed using fusion nanovesicles derived from plant and animal cells with high clinical potential. [ABSTRACT FROM AUTHOR]

Published

2023

3. Plant exosomes fused with engineered mesenchymal stem cell‐derived nanovesicles for synergistic therapy of autoimmune skin disorders

Author

Rufan Huang, Bo Jia, Dandan Su, Manchun Li, Zhanxue Xu, Chao He, Yisheng Huang, Hang Fan, Hongbo Chen, and Fang Cheng

Subjects

autoimmune diseases, CCR6, CX5461, exosome‐like nanovesicles, fusion vesicles, Cytology, QH573-671

Abstract

Abstract Existing therapeutics for autoimmune diseases remain problematic due to low efficacy, severe side effects, and difficulties to reach target tissues. Herein, we design multifunctional fusion nanovesicles that can target lesions for the treatment of autoimmune skin diseases. The grapefruit‐derived exosome‐like nanovesicles (GEVs) with anti‐inflammatory and antioxidant effects are first encapsulated with CX5461, an immunosuppressant with anti‐proliferative properties to form GEV@CX5461. In order to enhance therapeutic efficiency and safety, GEV@CX5461 are then fused with CCR6+ nanovesicles derived from membranes of engineered gingiva‐derived mesenchymal stem cells (GMSCs). The resulting FV@CX5461 not only maintain the bioactivity of GEVs, CX5461, and GMSC membranes but also home to inflamed tissues rich in chemokine CCL20 through the chemotaxis function of CCR6 on FVs. Moreover, FV@CX5461 reduce the secretion of inflammatory factors, calm down Th17 cell activation, and induce Treg cell infiltration. Finally, impressive therapeutic efficiency in both psoriasis and atopic dermatitis disease models is demonstrated using FV@CX5461 to reshape the unbalanced immune microenvironment. A nanotherapeutic drug delivery strategy is developed using fusion nanovesicles derived from plant and animal cells with high clinical potential.

Published

2023