Project description:Identifying signals that govern the differentiation of tumor-infiltrating CD8 + T cells (CD8 + TILs) towards exhaustion can improve current therapeutic approaches for cancer. Here, we show that type I interferons (IFN-Is) act as environmental cues enhancing terminal CD8 + T cell exhaustion in tumors. We found enrichment of IFNIs-stimulated genes (ISGs) within exhausted CD8 + T cells (Tex cells) in patients across various cancer types, with heightened ISG levels correlating with poor response to immune checkpoint blockade (ICB) therapy. In preclinical models, CD8 + TILs devoid of IFN-Is signaling developed less exhaustion features, provided better tumor control and showed greater response to ICB-mediated rejuvenation. Mechanistically, chronic IFN-Is stimulation perturbed lipid metabolism and redox balance in Tex cells, leading to aberrant lipid accumulation and elevated oxidative stress. Collectively, these defects promoted lipid peroxidation, which potentiated metabolic and functional exhaustion of Tex cells. Thus, cell intrinsic IFN-Is signaling regulates the extent of CD8+ TIL exhaustion, and has important implications for immunotherapy.

Project description:Identifying signals that govern the differentiation of tumor-infiltrating CD8 + T cells (CD8 + TILs) towards exhaustion can improve current therapeutic approaches for cancer. Here, we show that type I interferons (IFN-Is) act as environmental cues enhancing terminal CD8 + T cell exhaustion in tumors. We found enrichment of IFNIs-stimulated genes (ISGs) within exhausted CD8 + T cells (Tex cells) in patients across various cancer types, with heightened ISG levels correlating with poor response to immune checkpoint blockade (ICB) therapy. In preclinical models, CD8 + TILs devoid of IFN-Is signaling developed less exhaustion features, provided better tumor control and showed greater response to ICB-mediated rejuvenation. Mechanistically, chronic IFN-Is stimulation perturbed lipid metabolism and redox balance in Tex cells, leading to aberrant lipid accumulation and elevated oxidative stress. Collectively, these defects promoted lipid peroxidation, which potentiated metabolic and functional exhaustion of Tex cells. Thus, cell intrinsic IFN-Is signaling regulates the extent of CD8+ TIL exhaustion, and has important implications for immunotherapy.

Project description:CD8+ T cells isolated from HCC tissue were divided into three groups: PD1-TIM3- CD8+ TILs, exhibiting full effector function; PD1-intTIM3+ CD8+ TILs, exhibiting partial exhaustion; and PD1-hiTIM3+ CD8+ TILs, exhibiting severe exhaustion, as reflected by the differences in their ability to produce effector cytokines respectively. Transcriptome sequence analysis was performed to investigate the gene expression profile was performed.

Project description:T cell metabolic fitness plays a pivotal role in anti-tumor immunity and metabolic deregulation causes T cell dysfunction in cancer. We identify that CD36 limits anti-tumor CD8+ T cell effector functions through lipid peroxidation. In murine tumors, oxidized phospholipids (OxPLs) were highly abundant and CD8+ TILs increased uptake and accumulation of lipids and lipid peroxidation. Functionally ‘exhausted’ CD8+ TILs increased CD36 expression and CD36-deficient CD8+ TILs had more robust anti-tumor activity and cytokine production than wild-type cells. We further show that CD36 promotes uptake of oxidized low-density lipoproteins (OxLDL), induces lipid peroxidation in CD8+ TILs, and enhances p38 kinase phosphorylation. Moreover, we found that OxLDL inhibits CD8+ T cell functions in a CD36/p38-dependent manner. Furthermore, glutathione peroxidase 4 (GPX4) over-expression lowers lipid peroxidation and restores functionalities in CD8+ TILs. These results define a key role for an oxidized lipid-CD36-p38 axis in promoting intratumoral CD8+ T cell dysfunction.

Project description:CD8+ tumor infiltrating lymphocytes (TILs) are associated with improved survival in triple negative breast cancer (TNBC), yet have no association with survival in estrogen receptor-positive (ER+) BC. The basis for these contrasting findings remains elusive. We identify subsets of BC tumors infiltrated by CD8+ T cells with characteristic features of exhausted T cells (TEX). Tumors with abundant CD8+ TEX exhibit a distinct tumor microenvironment marked by amplified interferon-γ signaling related pathways and higher PD-L1 expression. Paradoxically, high levels of CD8+ TEX TILs associate with decreased overall survival ER+ BC patients, but not TNBC patients. Moreover, high tumor expression of a CD8+ TEX signature identifies dramatically reduced survival in pre-menopausal, but not post-menopausal, ER+ BC patients. Finally, we demonstrate the value of a tumor TEX signature score in identifying high-risk pre-menopausal ER+ BC patients amongst those with intermediate Oncotype Dx breast recurrence scores. Our data highlight the complex relationship between CD8+ TILs, interferon-γ signaling, and estrogen receptor status in BC patient survival. This work identifies pre-menopausal ER+ BC patients with high levels of tumor infiltrating CD8+ TEX as a high-risk subset that may benefit from immunotherapy strategies.

Project description:Current cancer immunotherapies promote recovery of CD103+ tissue-resident memory T cells (Trm) population of the tumor-infiltrating T lymphocytes (TILs). However, not all treated patients exhibit improved anti-tumor immunity and survival, likely due to the immunophenotypical diversity among the CD103+ Trm TILs. Utilising multifaceted proteomics approaches and patients’ clinical analyses, we discovered an unusual subset of CD8+ Trm TILs expressing non-canonical integrin β3 early during T cells activation. The integrin β3 surprisingly heterodimerises with CD103 on T cells, leading to unconventional granulysin-mediated cytotoxicity, elevated alternative bioenergy usage and efficient T cell migration, with minimal overall exhaustion. Importantly, early-stage non-small cell lung carcinoma (NSCLC) patients with enriched presence of integrin β3+CD103+ Trm TILs exhibited better clinical prognosis, with improved T cell immunophenotype, hence confirming the beneficial role of this unusual subset of Trm TILs. These unconventional anti-tumor T cell features provide new avenues and future opportunities for designing better translational immunotherapy strategies.

Project description:CD8+ T cell exhaustion (TEX) impairs the ability of T cells to clear chronic infection or cancer. While TEX are hypofunctional, some TEX retain effector gene signatures, a feature that is associated with expression of KLRs (killer lectin-like receptors). Although KLR+ TEX may improve control of chronic antigen, the signaling molecules regulating this population are poorly understood. Using scRNA-seq, flow cytometry, RNA velocity, and scTCR-seq, we demonstrated that deleting the pseudokinase Trib1 shifted TEX towards CX3CR1+ intermediates (TINT) with robust enrichment of KLR+ TEX (TKLR) via clonal T cell expansion. Adoptive transfer studies demonstrate this shift towards a CD8+ TKLR in Trib1 deficient cells is CD8-intrinsic, while CD4-depletion studies demonstrate that CD4+ T cells are required for optimal viral control in Trib1 conditional knockout mice. Further, Trib1 loss augmented anti-PD-L1 blockade to improve viral clearance. These data identify Trib1 as an important regulator of CD8+ TEX whose targeting enhances the TKLR effector state and improves checkpoint inhibitor therapy.

Project description:We then investigated how HPK1 induces new changes by comparing the open chromatin regions (OCRs) with WT control and founded that the ATAC-seq tracks were aligned with the previously reported OCRs of exhausted . HPK1 knockout induced loss of peaks in loci enriched in exhausted T (Tex) cells (e.g., PD-1, TIM-3, LAG-3, and TOX locus), indicating that HPK1 knockout could overcome some negative effects caused by TME, ameliorate T cell exhaustion and thus extend their effector function (Figure S2F). Moreover, we also found that more accessible regions in HPK1-knockout CD8+TILs showed significant enrichment for pathways associated with cell cycle, antigen processing and presentation, T cell receptor signaling, Glyoxylate and dicarboxylate metabolism, AMPK pathway, and C-type lectin receptor signaling pathway (Figure S2G). It has been demonstrated that many peak changes were unique to either the early dysfunctional or functional state and included TCR signaling and cytokine production pathway genes. Pauken and the colleagues identified two metagenes in anti-PD-L1–treated exhausted T cell (TEX) compared to control TEX; one corresponding to leukocyte activation and one to cell cycle. The anti-PD-L1–treated TEX metagenes displayed some overlap with effector T cells (TEFF), largely driven by cell cycle pathways, but minimal overlap with Memory T cell (TMEM). Thus, we concluded that HPK1-/- TILs are prone to be effort T cells defined according to the chromatin states.

Project description:Interferon-gamma (IFNG) augments immune function yet promotes T cell exhaustion through PDL1. How these opposing effects are integrated to impact immune checkpoint blockade (ICB) is unclear. We show that while inhibiting tumor IFNG signaling decreases interferon-stimulated genes (ISGs) in cancer cells, it increases ISGs in immune cells by enhancing IFNG produced by exhausted T cells (TEX). In tumors with favorable antigenicity, these TEX mediate rejection. In tumors with neoantigen or MHC-I loss, TEX instead utilize IFNG to drive maturation of innate immune cells, including a PD1+TRAIL+ ILC1 population. By disabling an inhibitory circuit impacting PD1 and TRAIL, blocking tumor IFNG signaling promotes innate immune killing. Thus, interferon signaling in cancer cells and immune cells oppose each other to establish a regulatory relationship that limits both adaptive and innate immune killing. In melanoma and lung cancer patients, perturbation of this relationship is associated with ICB response independent of tumor mutational burden.

Project description:Interferon-gamma (IFNG) augments immune function yet promotes T cell exhaustion through PDL1. How these opposing effects are integrated to impact immune checkpoint blockade (ICB) is unclear. We show that while inhibiting tumor IFNG signaling decreases interferon-stimulated genes (ISGs) in cancer cells, it increases ISGs in immune cells by enhancing IFNG produced by exhausted T cells (TEX). In tumors with favorable antigenicity, these TEX mediate rejection. In tumors with neoantigen or MHC-I loss, TEX instead utilize IFNG to drive maturation of innate immune cells, including a PD1+TRAIL+ ILC1 population. By disabling an inhibitory circuit impacting PD1 and TRAIL, blocking tumor IFNG signaling promotes innate immune killing. Thus, interferon signaling in cancer cells and immune cells oppose each other to establish a regulatory relationship that limits both adaptive and innate immune killing. In melanoma and lung cancer patients, perturbation of this relationship is associated with ICB response independent of mutational burden.