Project description:The aim of the experiment was to understand the clonal relationship between CD8+ central memory blood T cells (TCM) and the in-vivo matured TCM tissue-resident memory-like T cells (TRM) on day 14. TCM were FACS sorted from human PBMCs (n=5). Half of the cells were processed on day 1 and half of the cells of each donor were matured into TRM with anti-CD3, IL-15 and TGF beta for 14 days. Both day 1 TCM and matured day 14 TRM-like cells were further processed using the 5´10X genomics workflow.

Project description:Tissue-resident CD8+ memory T (TRM) cells are immune cells that permanently reside at tissue sites where they play an important role in providing rapid protection against reinfection. They are not only phenotypically and functionally distinct from their circulating memory counterparts, but also exhibit a unique transcriptional profile. To date, the local tissue signals required for their development and long-term residency are not well understood. So far, the best-characterised tissue-derived signal is transforming growth factor-β (TGF-β), which has been shown to promote the development of these cells within tissues. In this study, we aimed to determine to what extent the transcriptional signatures of TRM cells from multiple tissues reflects TGF-β imprinting. We activated murine CD8+ T cells, stimulated them in vitro by TGF-β, and profiled their transcriptomes using RNA-seq. Upon comparison, we identified a TGF-β-induced signature of differentially expressed genes between TGF-β-stimulated and -unstimulated cells. Next, we linked this in vitro TGF-β-induced signature to a previously identified in vivo TRM-specific gene set and found considerable (>50%) overlap between the two gene sets, thus showing that a substantial part of the TRM signature can be attributed to TGF-β signalling. Finally, gene set enrichment analysis further revealed that the altered gene signature following TGF-β exposure reflected transcriptional signatures found in TRM cells from both epithelial and non-epithelial tissues. In summary, these findings show that TGF-β has a broad footprint in establishing the residency-specific transcriptional profile of TRM cells, which is detectable in TRM cells from diverse tissues. They further suggest that constitutive TGF-β signaling might be involved for their long-term persistence at tissue sites.

Project description:TGF-beta signaling is required for the differentiation of gut-resident memory CD8 T cells. Here, we showed that the deficiency of transcription factor T-bet partially rescued the differentiation of TGF-beta receptor deficient gut-resident memory CD8 T cells. Hic1 induction further strengthens TRM maturation in the absence of TGF-b and T-bet.

Project description:Transcriptional profiling of human umbilical vein endothelial cells following stimulation with tumour necrosis factor alpha and transforming growth factor beta singly or combined for 8 hr All stimulations were for 8 hr - TNF-α vs no cytokine; TGF-β1 vs no cytokine; TNF-α & TGF-β1 vs TNF-α alone; TNF-α & TGF-β1 vs TGF-β1 alone

Project description:Primary myelofibrosis (PMF) is a myeloproliferative neoplasm characterized by clonal expansion of myeloid cells, notably megakaryocytes (MKs), and aberrant cytokine production leading to bone marrow (BM) fibrosis and insufficiency. Current treatment options are limited. TGF-b1, a profibrotic and immunosuppressive cytokine, is involved in PMF pathogenesis. While all cell types secrete inactive, latent TGF-b1, only a few activate the cytokine via cell type-specific mechanisms. The cellular source of the active TGF-b1 implicated in PMF is not known. Transmembrane protein GARP binds and activates latent TGF-b1 on the surface of regulatory T lymphocytes (Tregs) and MKs or platelets. Here, we found increased expression of GARP in BM and spleen of mice undergoing PMF and tested the therapeutic potential of a monoclonal antibody that blocks TGF-b1 activation by GARP-expressing cells. GARP:TGF-b1 blockade reduced not only fibrosis, but also clonal expansion of transformed cells. Using mice carrying a genetic deletion of Garp in either Tregs or MKs, we found that the therapeutic effects of GARP:TGF-b1 blockade in PMF imply targeting GARP on Tregs. These therapeutic effects, accompanied by increased IFN-g signals in the spleen, were lost upon CD8 T cell depletion. Our results suggest that selective blockade of TGF-b1 activation by GARP-expressing Tregs increase a CD8 T cell-mediated immune reaction that limits transformed cell expansion, providing a novel approach that could be tested to treat patients with myeloproliferative neoplasms.

Project description:We have previously demonstrated that TNF-α, a proinflammatory cytokine, enhances TGF-β-mediated EMT in A549 human lung cancer cells. RNA-sequencing analysis on CMT64 cells following TGF-β and/or TNF-α treatment revealed a subset of genes possibly regulated by TGF-β and/or TNF-α.

Project description:SMAD4, a key mediator of TGF-beta signaling, plays a crucial role in T cells to prevent chronic intestinal inflammation through unknown mechanisms. We reveal that SMAD4 in CD8 T cells prevents chronic intestinal inflammation primarily in a TGF-beta-independent manner. Mechanistically, SMAD4, in CD8 T cells, acts as a basal and tonic repressor of TGF-beta-target genes at the transcriptional and epigenetic level, prior to any TGF-beta signal. SMAD4 deletion affects aberrantly a wide range of TGF-beta-target genes, thereby promoting accumulation and epithelial retention of CD8.alpha.beta T cells inversely to total TGF-beta signaling disruption. Moreover, SMAD4 deletion unleashes the expression of TGF-beta-signaling-repressors and hampers TGF-β-mediated CD8 T cell immunosuppression, eliciting their chronic activation. Hence, in a feedforward mechanism, SMAD4 both blocks the TGF-beta signature in CD8 T cells and pre-sensitizes them to TGF-beta.

Project description:SMAD4, a key mediator of TGF-beta signaling, plays a crucial role in T cells to prevent chronic intestinal inflammation through unknown mechanisms. We reveal that SMAD4 in CD8 T cells prevents chronic intestinal inflammation primarily in a TGF-beta-independent manner. Mechanistically, SMAD4, in CD8 T cells, acts as a basal and tonic repressor of TGF-beta-target genes at the transcriptional and epigenetic level, prior to any TGF-beta signal. SMAD4 deletion affects aberrantly a wide range of TGF-beta-target genes, thereby promoting accumulation and epithelial retention of CD8.alpha.beta T cells inversely to total TGF-beta signaling disruption. Moreover, SMAD4 deletion unleashes the expression of TGF-beta-signaling-repressors and hampers TGF-β-mediated CD8 T cell immunosuppression, eliciting their chronic activation. Hence, in a feedforward mechanism, SMAD4 both blocks the TGF-beta signature in CD8 T cells and pre-sensitizes them to TGF-beta.

Project description:Using mouse model, we show that CD8 tumor-infiltrating T lymphocytes (TIL) include two major resident T cells subpopulations expressing either CD49a or CD103 integrin, with a subset co-expressing CD103 and Tcf-1 transcription factor. Tumor vaccination induces a decrease in the percentage of Tcf-1+CD103+ TRM-like cells and an expansion of CD49a+ TRM displaying an effector/exhausted profile. Tcf-1+CD103+ TRM-cell density increases in tumors from vaccinated transgenic mice constitutively expressing active TGF-beta-type-2-receptor and wild-type mice challenged with neutralizing anti-IL-12 antibodies. Stimulation of mouse and human CD8 T cells with recombinant (r)TGF-beta combined with anti-CD3 antibodies results in increase in the proportion of CD103+ and Tcf-1+CD103+ CD8 T cells, whereas rIL-12 induces decrease in CD103 expression on CD8 T cells.

Project description:Immune checkpoint blockade (ICB) has revolutionized cancer immunotherapy. However, the majority of cancer patients fail to respond clinically. One potential reason is the accumulation of transforming growth factor-beta (TGFb) in the tumor microenvironment (TME). TGFb drives cancer immune evasion in part by inducing regulatory T cells (Tregs) and limiting CD8+ T cell function. Glycoprotein-A repetitions predominant (GARP) is a cell surface docking receptor for activating latent TGF1, TGFb2 and TGFb3, with its expression restricted in effector Tregs, cancer cells as well as platelets. Herein we demonstrate that GARP overexpression in human cancers correlates with unfavorable TME and poor clinical response to ICB, raising a possibility of GARP blockade to improve cancer immunotherapy. However, it is unclear if targeting GARP in the TME is feasible without affecting platelets. We report an anti-human GARP antibody (named PIIO-1) specific for its ligand-interacting domain, effectively blocking activation of latent TGFb1. PIIO-1 lacks recognition of GARP-TGF complex on platelets. Using human GARP knock-in mice, we demonstrate that PIIO-1 does not cause thrombocytopenia, and is preferentially distributed in the TME and effective for treating both GARP+ and GARP- cancers, alone or in combination with anti-PD-1 antibody. PIIO-1 treatment reduces canonical TGFb signaling in tumor-infiltrating immune cells, prevents T cell exhaustion, and enhances CD8+ T cell migration into the TME in a CXCR3-dependent manner. Collectively, we conclude that GARP contributes to multiple aspects of immune resistance in cancer; anti-GARP antibody PIIO-1 is an efficacious and safe strategy to overcome ICB resistance, therefore warranting clinical development.