Malignancy and tumour progression are associated with cancer-cell softening. Yet how the biomechanics of cancer cells affects T-cell mediated cytotoxicity and thus the outcomes of adoptive T-cell immunotherapies is unknown. Here, we show that T-cell-mediated cancer-cell killing is hampered for cortically soft cancer cells, whose plasma membrane is enriched with cholesterol, and that cancer-cell stiffening via cholesterol depletion augments T-cell cytotoxicity and enhances the efficacy of adoptive T-cell therapy against solid tumours in mice. We also show that the enhanced cytotoxicity against stiffened cancer cells is mediated by augmented T-cell forces arising from an increased accumulation of filamentous actin at the immunological synapse, and that cancer-cell stiffening has a negligible influence on T-cell-receptor signalling, on the production of cytolytic proteins such as granzyme B, on the secretion of interferon gamma and tumour necrosis factor alpha, and on Fas-receptor–Fas-ligand interactions. Our findings reveal a mechanical immune checkpoint that could be targeted therapeutically to improve the effectiveness of cancer immunotherapies.
Cancer cells enriched with cholesterol in their plasma membrane impair T-cell mediated cytotoxicity, which can be augmented by stiffening the cancer cells via cholesterol depletion, as shown in mouse models of adoptive T-cell therapy.
Targeting the stimulator of interferon genes (STING) pathway with cyclic dinucleotides (CDNs), the natural STING agonists, is a promising immunotherapeutic strategy for cancer. However, the clinical application of natural CDNs as therapeutics is greatly hindered by their intrinsic properties including negative charges, small molecular weight, and high susceptibility to enzymatic degradation. Mn 2+ ions have been recently discovered to directly activate the cyclic GMP-AMP (cGAMP) synthase (cGAS) and augment cGAMP-STING binding affinity. Here, a PEGylated manganese(II) phosphate (MnP-PEG) nanocluster is developed with high biocompatibility and potent capacity to stimulate the cGAS-STING pathway. MnP-PEG nanoclusters activate the immature bone marrow-derived dendritic cells (DCs) leading to 57.3-and 13.3-fold higher production of interferon and interleukin-6 than free cGAMP, respectively. The potent STING activation capacity is likely due to the efficient cellular internalization of MnP-PEG nanoclusters by DCs and acid-triggered release of Mn 2+ ions in the endolysosomes. Intratumoral administration of MnP-PEG nanoclusters markedly enhances tumor infiltration as well as maturation of DCs and macrophages, and promotes activation and cytotoxicity of T cells and natural killer cells in the tumor. MnP-PEG nanocluster in combination with a checkpoint inhibitor leads to significant tumor regression in the B16F10 murine melanoma model without any overt toxicities.
This work reports a redox-responsive nanogel backpack on the T cell surface for T cell receptorsignaling-triggered cytokine release, which boosts adoptive T cell therapy against solid tumors.
No T cell receptor (TCR) T cell therapies have obtained clinical approval. The lack of strategies capable of selecting and recovering potent T cell candidates may be a contributor to this. Existing protocols for selecting TCR T cell clones for cell therapies such as peptide multimer methods have provided effective measurements on TCR affinities. However, these methods lack the ability to measure the collective strength of intercellular interactions (i.e., cellular avidity) and markers of T cell activation such as immunological synapse formation. This study describes a novel microfluidic fluid shear stress‐based approach to identify and recover highly potent T cell clones based on the cellular avidity between living T cells and tumor cells. This approach is capable of probing approximately up to 10 000 T cell–tumor cell interactions per run and can recover potent T cells with up to 100% purity from mixed populations of T cells within 30 min. Markers of cytotoxicity, activation, and avidity persist when recovered high cellular avidity T cells are subsequently exposed to fresh tumor cells. These results demonstrate how microfluidic probing of cellular avidity may fast track the therapeutic T cell selection process and move the authors closer to precision cancer immunotherapy.
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