Project description:While distinct NK-like CD57+ and PD-1+ CD8+ exhausted T cell populations (Tex) were both linked to beneficial immunotherapy response in autoimmune Type 1 Diabetes (T1D) patients, relationships between these cell types are poorly understood. We show that PD-1+ and CD57+ Tex populations in this context were epigenetically similar, but CD57+ Tex cells displayed unique increased chromatin accessibility of inhibitory Killer Cell Immunoglobulin-like Receptor (iKIR) and other NK cell genes. PD-1+ and CD57+ Tex also showed reciprocal expression of Inhibitory Receptors (IRs) and iKIRs accompanied by chromatin accessibility of Tcf1 and Tbet transcription factor target sites, respectively. CD57+ Tex showed unappreciated gene expression heterogeneity and shared clonal relationships with PD-1+ Tex, with these cells differentiating along four interconnected lineage trajectories: Tex-PD-1+, Tex-CD57+, Tex-Branching, and Tex-Fluid. Our findings demonstrate new relationships between Tex populations in human autoimmune disease and suggest that modulating common precursor populations may enhance response to autoimmune disease treatment.

Project description:NK cells are lymphocytes that provide a first defense against viral infections and cancer. They act (i) cytotoxic by killing virus-infected and tumorigenic cells and (ii) immune regulatory by releasing cytokines and chemokines. These innate immune cells are commonly further classified as CD56bright and CD56dim NK cells. Former studies confirmed immune regulatory CD56bright NK cells as progenitors of cytotoxic CD56dim NK cells. CD57 was previously described as T cell marker for senescence and terminal differentiation. Recent studies detected CD57+ and CD57- NK cells among the CD56dim NK cell population and suggested a fully mature developmental status for CD57+ NK cells. The recent NK cell maturation model includes CD34+ hematopoietic stem cells (HSC), which develop into CD56bright NK cells, later into CD56dimCD57- and finally into terminally maturated CD56dimCD57+ (1) (2) (3). The molecular mechanisms of human NK cell differentiation and maturation remain unknown to this date. We performed for the first time a proteomic analysis of these distinct developmental stages of human primary NK cells, isolated from overall 10 healthy human blood donors. CD56bright NK cells versusCD56dim and CD56dimCD57- versus CD56dimCD57+ NK cells were analyzed by using quantitative peptide sequencing, which revealed individual protein signatures (3400 proteins) of these different NK cell developmental stages. Notably, our data support the current NK cell differentiation model by highlighting both strong distinctions between CD56dim/bright NK cells and close relationships between CD57+/- NK cells on the proteomic level. Among the most prominent and conserved regulated proteins, we detected myosin IIa, Calvasculin and Calcyclin with very similar expression patterns. We investigated their sub-cellular localization and observed specific recruitment- and accumulation-events at the NK cell immunological synapse (NKIS) after NK activation.

Project description:Human Natural Killer (NK) cells in peripheral blood perform many functions but classification of specific subsets has been a long-standing problem. Here, we report single-cell RNA sequencing of NK cells from healthy CMV-negative donors, comparing gene expression in unstimulated and IL-2 activated cells. Unsupervised clustering identified seven NK cell subsets. Three resembled well-described populations, CD56brightCD16-, CD56dimCD16+CD57- and CD56dimCD16+CD57+. CD56dimCD16+CD57- cells sub-divided to include a population with higher chemokine mRNA and increased frequency of KIR expression. Three novel human blood NK cell populations were identified as: a population of type I interferon responding NK cells which were CD56neg; a population exhibiting an in-vivo cytokine-induced memory-like phenotype, including increased granzyme B mRNA in response to IL-2, and finally, a small population, with low ribosomal expression, down-regulation of oxidative phosphorylation and high levels of immediate early response genes indicative of cellular activation. Human cytomegalovirus positive donors also included a higher frequency of adaptive NK cells. Together, these data establish an unexpected diversity in blood NK cells and provide a new framework for analysing NK cell responses in health and disease.

Project description:Thirty to 60% of CD56dimCD16bright NK cells in healthy adults express CD57, which is not expressed on immature CD56bright NK cells or fetal and newborn NK cells. We hypothesized that CD57+ NK cells within the CD56dim mature NK cell subset are highly mature and might be terminally differentiated. We used microarrays to assess the transcriptional differences between CD57+ and CD57neg NK cells within the CD56dim mature NK subset.

Project description:Human Natural Killer (NK) cells in peripheral blood perform many functions and classification of specific subsets has been a long-standing goal. Here, we report single cell RNA-sequencing of NK cells, comparing gene expression in unstimulated and IL-2 activated cells, from healthy CMV-negative donors. Three NK cell subsets resembled well-described populations, CD56brightCD16-, CD56dimCD16+CD57- and CD56dimCD16+CD57+. CD56dimCD16+CD57- cells sub-divided to include a population with higher chemokine mRNA and increased frequency of KIR expression. Three novel human blood NK cell populations were identified as: a population of type I interferon responding NK cells which were CD56neg, a population exhibiting a cytokine-induced memory-like phenotype, including increased granzyme B mRNA in response to IL-2, and finally, a small population, with low ribosomal expression, down-regulation of oxidative phosphorylation and high levels of immediate early response genes indicative of cellular activation. Analysis of CMV-positive donors established that CMV altered the proportion of NK cells in each subset, especially an increase in adaptive NK cells, as well as gene regulation within each subset. Together, these data establish an unexpected diversity in blood NK cells and provide a new framework for analysing NK cell responses in health and disease.

Project description:Here, we discovered a reciprocal antagonism between Stat5a and Tox in TEX cells. Stat5a antagonized the Tox-mediated exhaustion program to achieve a durable and protective hybrid effector/NK-like differentiation state in settings that typically drive exhaustion. Stat5 also drove TEX progenitors to differentiate into the effector-like TEXint subset, a key developmental step for PD-1 blockade responsiveness.

Project description:Here, we discovered a reciprocal antagonism between Stat5a and Tox in TEX cells. Stat5a antagonized the Tox-mediated exhaustion program to achieve a durable and protective hybrid effector/NK-like differentiation state in settings that typically drive exhaustion. Stat5 also drove TEX progenitors to differentiate into the effector-like TEXint subset, a key developmental step for PD-1 blockade responsiveness.

Project description:Human skin harbors two major T cell compartments of equal size that are distinguished by expression of the chemokine receptor CCR8. In vitro studies have demonstrated that CCR8 expression is under strict control of T cell antigen receptor (TCR)-engagement and the skin tissue microenvironment. We here examined the relationship between CCR8+ and CCR8− T cells. Phenotypic, functional, and transcriptomic analyses revealed that CCR8+ skin T cells bear all the hallmarks of resident memory T (TRM) cells, including homeostatic proliferation in response to IL-7 and IL-15, surface expression of tissue-localization (CD103) and -retention (CD69) markers, low levels of inhibitory receptors (PD-1, Tim-3, LAG-3), and a lack of senescence markers (CD57, KLRG1). In contrast, CCR8− skin T cells are heterogeneous and comprise variable numbers of exhausted (PD-1+), senescent (CD57+, KLRG1+), and effector (T-bethi, Eomeshi) T cells. Importantly, conventional and high-throughput analyses of expressed T cell receptor beta-chain (TRB) gene rearrangement sequences showed that the two skin memory T cell compartments distinguished by CCR8 expression are clonotypically distinct, suggesting that they are produced in response to separate antigenic challenges and distinct stimulatory conditions. Moreover, the phenotypic profiles of these populations were stable in vitro and the presence of similar levels of telomere erosion excludes the possibility of a linear differentiation pathway. In conclusion, CCR8 marks skin-specific, long-lived memory T cells. Therefore, we propose that CCR8+ T cells should be targeted in future skin vaccination research.

Project description:Here, we discovered a reciprocal antagonism between Stat5a and Tox in TEX cells. Stat5a antagonized the Tox-mediated exhaustion program to achieve a durable and protective hybrid effector/NK-like differentiation state in settings that typically drive exhaustion. Stat5 also drove TEX progenitors to differentiate into the effector-like TEXint subset, a key developmental step for PD-1 blockade responsiveness. Therapeutic enhancement of Stat5 activity in TEX cells using an orthogonal IL-2/IL2Rb pair system fostered TEXint cell accumulation and synergized with PD-L1 blockade. Finally, targeted delivery of Stat5-signals in TEX progenitors achieved partial epigenetic rewiring of these cells towards the effector/memory lineage and revived polyfunctionality. Together, these data highlight therapeutic opportunities of targeting Stat5 to antagonize the Tox-dependent epigenetic programming of TEX and provoke a hybrid program that exploits effector biology and durability for optimal therapeutic potential

Project description:Here, we discovered a reciprocal antagonism between Stat5a and Tox in TEX cells. Stat5a antagonized the Tox-mediated exhaustion program to achieve a durable and protective hybrid effector/NK-like differentiation state in settings that typically drive exhaustion. Stat5 also drove TEX progenitors to differentiate into the effector-like TEXint subset, a key developmental step for PD-1 blockade responsiveness. Therapeutic enhancement of Stat5 activity in TEX cells using an orthogonal IL-2/IL2Rb pair system fostered TEXint cell accumulation and synergized with PD-L1 blockade. Finally, targeted delivery of Stat5-signals in TEX progenitors achieved partial epigenetic rewiring of these cells towards the effector/memory lineage and revived polyfunctionality. Together, these data highlight therapeutic opportunities of targeting Stat5 to antagonize the Tox-dependent epigenetic programming of TEX and provoke a hybrid program that exploits effector biology and durability for optimal therapeutic potential