Acquisition of suppressive function by conventional T cells limits antitumor immunity upon T reg depletion.
Sarah K WhitesideFrancis M GrantGiorgia AlvisiJames ClarkeLeqi TangCharlotte J ImianowskiBaojie ZhangAlexander C EvansAlexander J WesolowskiAlberto G ContiJie YangSarah Nicol LauderMathew ClementIan R HumphreysJames DooleyOliver T BurtonAdrian ListonMarco AlloisioEmanuele VoulazJean LanghorneKlaus OkkenhaugEnrico LugliRahul RoychoudhuriPublished in: Science immunology (2023)
Regulatory T (T reg ) cells contribute to immune homeostasis but suppress immune responses to cancer. Strategies to disrupt T reg cell-mediated cancer immunosuppression have been met with limited clinical success, but the underlying mechanisms for treatment failure are poorly understood. By modeling T reg cell-targeted immunotherapy in mice, we find that CD4 + Foxp3 - conventional T (T conv ) cells acquire suppressive function upon depletion of Foxp3 + T reg cells, limiting therapeutic efficacy. Foxp3 - T conv cells within tumors adopt a T reg cell-like transcriptional profile upon ablation of T reg cells and acquire the ability to suppress T cell activation and proliferation ex vivo. Suppressive activity is enriched among CD4 + T conv cells marked by expression of C-C motif receptor 8 (CCR8), which are found in mouse and human tumors. Upon T reg cell depletion, CCR8 + T conv cells undergo systemic and intratumoral activation and expansion, and mediate IL-10-dependent suppression of antitumor immunity. Consequently, conditional deletion of Il10 within T cells augments antitumor immunity upon T reg cell depletion in mice, and antibody blockade of IL-10 signaling synergizes with T reg cell depletion to overcome treatment resistance. These findings reveal a secondary layer of immunosuppression by T conv cells released upon therapeutic T reg cell depletion and suggest that broader consideration of suppressive function within the T cell lineage is required for development of effective T reg cell-targeted therapies.
Keyphrases
- induced apoptosis
- single cell
- cell cycle arrest
- cell therapy
- regulatory t cells
- endoplasmic reticulum stress
- signaling pathway
- type diabetes
- oxidative stress
- gene expression
- stem cells
- adipose tissue
- cell death
- poor prognosis
- mesenchymal stem cells
- squamous cell carcinoma
- skeletal muscle
- cell proliferation
- dna methylation
- bone marrow
- papillary thyroid
- metabolic syndrome
- replacement therapy
- heat shock
- high fat diet induced
- heat shock protein
- drug induced
- squamous cell