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Mechanoimmune-Driven Backpack Sustains Dendritic Cell Maturation for Synergistic Tumor Radiotherapy

Huan Yu, Zhan Liu, Haoxiang Guo, Xuying Hu, Yangyun Wang, Yangyun Wang, Xiaju Cheng, Leshuai W. Zhang, Yong Wang, Yong Wang

2024ACS Nano23 citationsDOI

Abstract

Cell backpacks present significant potential in both therapeutic and diagnostic applications, making it essential to further explore their interactions with host cells. Current evidence indicates that backpacks can induce sustained immune responses. Our original objective was to incorporate a model antigen into the backpacks to promote dendritic cell maturation and facilitate antigen presentation, thereby inducing immune responses. However, we unexpectedly discovered that both antigen-loaded backpacks and empty backpacks demonstrated comparable abilities to induce dendritic cell maturation, resulting in nearly identical potency in T-cell proliferation. Our mechanistic studies suggest that the attachment of backpacks induces mechanical forces on dendritic cells via opening the PIEZO1 mechanical ion channel. This interaction leads to the remodeling of the intracellular cytoskeleton and facilitates the production of type I interferons by dendritic cells. Consequently, the mechano-immune-driven dendritic cell backpacks, when combined with radiotherapy, induce a robust antitumor effect. This research presents an avenue for leveraging mechanotransduction to enhance combination immunotherapeutic strategies, potentially leading to groundbreaking advancements in the field.

Topics & Concepts

BackpackRadiation therapyDendritic cellNanotechnologyCancer researchMedicineMaterials scienceImmune systemInternal medicineImmunologyEngineeringStructural engineeringImmunotherapy and Immune ResponsesRNA Interference and Gene DeliveryPhagocytosis and Immune Regulation
Mechanoimmune-Driven Backpack Sustains Dendritic Cell Maturation for Synergistic Tumor Radiotherapy | Litcius