Project description:During chronic viral infection, CD8 T cells lose effector function and acquire an exhausted phenotype, a process accompanied by changes in migratory behavior and tissue residency. Exhausted CD8 T cells differentiate from stem-like progenitor (Tpro) cells into either circulating, cytotoxic effector-like (Teff) cells or tissue-resident terminally exhausted (Texh) cells. However, whether these migratory changes passively reflect cell state or actively influence exhaustion trajectories remains unclear. Here, we identify a transcriptional circuit involving Krüppel-like factor 2 (KLF2) and its homolog KLF3 that links migratory program to CD8 T cell differentiation during exhaustion. Using multi-module approaches, we show that KLF2 primarily promotes the expression and chromatin accessibility of migratory genes in Tpro and Teff subsets, while KLF3 limits these programs by repressing Klf2 transcription and competing for shared genomic binding sites. Enhancing circulation through enforced S1PR1/S1PR5 expression or CD69 deletion biases differentiation toward effector-like fates and away from terminal exhaustion, suggesting that cellular localization can influence, not just reflect, CD8 T cell fate decisions. We further describe an integrated feed-forward and feedback loop in which KLF2 induces KLF3, which in turn constrains KLF2 transcription and binding to shared genomic loci. This reciprocal regulatory circuit modulates the balance between migration and tissue residency, thereby tuning the differentiation of CD8 T cells in chronic infection. These findings provide mechanistic insight into how transcriptional regulation of migratory behavior contributes to cell fate decisions during T cell exhaustion.

Project description:Numerous transcriptional regulators have been associated with the differentiation pathways that lead to recirculating versus tissue-resident memory T cells. However, it is unclear whether independent, coordinated expression of these regulators is required to determine residency versus recirculation, or whether there is a hierarchy, with some factors playing a dominant role in controlling T cell trafficking. We report that ablation of the gene encoding Kruppel-like factor 2 (KLF2) during CD8+ T cell activation leads to rapid transcriptional reprograming, such that effector T cells fail to recirculate and prematurely acquire canonical phenotypic and transcriptional characteristics of resident memory cells (TRM). Klf2-deficient memory CD8+ T cells retained the capacity to undergo recall responses, including in vivo pathogen control. These data suggest KLF2 diverts CD8+ T cells from the TRM differentiation program. In contrast, ablation of another member of the KLF family, KLF3, enhanced differentiation of some recirculating T cell subsets and limited production of TRM in lymphoid tissues. However, both KLF2 and KLF3 were required for differentiation of long-lived effector cells, suggesting cooperation between these factors in some situations. These findings indicate KLFs occupy a central nexus in coordinating activated CD8+ T cell differentiation and trafficking.

Project description:Numerous transcriptional regulators have been associated with the differentiation pathways that lead to recirculating versus tissue-resident memory T cells. However, it is unclear whether independent, coordinated expression of these regulators is required to determine residency versus recirculation, or whether there is a hierarchy, with some factors playing a dominant role in controlling T cell trafficking. We report that ablation of the gene encoding Kruppel-like factor 2 (KLF2) during CD8+ T cell activation leads to rapid transcriptional reprograming, such that effector T cells fail to recirculate and prematurely acquire canonical phenotypic and transcriptional characteristics of resident memory cells (TRM). Klf2-deficient memory CD8+ T cells retained the capacity to undergo recall responses, including in vivo pathogen control. These data suggest KLF2 diverts CD8+ T cells from the TRM differentiation program. In contrast, ablation of another member of the KLF family, KLF3, enhanced differentiation of some recirculating T cell subsets and limited production of TRM in lymphoid tissues. However, both KLF2 and KLF3 were required for differentiation of long-lived effector cells, suggesting cooperation between these factors in some situations. These findings indicate KLFs occupy a central nexus in coordinating activated CD8+ T cell differentiation and trafficking.

Project description:RNA sequencing of human CD8+ T cell subsets to compare hypofunctional exhausted cells (TEX) to fully activated effector cells (TEFF).

Project description:Chronic infections and cancer cause T cell dysfunction known as exhaustion due to persistent antigen exposure, suboptimal co-stimulation and a plethora of hostile factors, which dampens protective immunity and limits the efficacy of immunotherapies1-4. The mechanisms behind T cell exhaustion remain poorly understood. Herein, we dissected the proteome of CD8+ exhausted T cells (Tex) across multiple states of exhaustion in the context of both chronic viral infections and cancer. We found that there was a non-stochastic pathway-specific discordance between mRNA and protein dynamics in T effector (Teff) versus Tex cells. We identified a unique proteostatic stress response (PSR) in Tex cells which we termed TexPSR. Contrary to canonical stress responses with reduced protein synthesis5,6, the TexPSR involves increased global translation activity and an upregulation of specialized chaperones, characterized further by the accumulation of protein aggregates, stress granules and autophagy-dominant protein catabolism. We established that disruption of proteostasis alone can convert Teff to Tex cells, and linked TexPSR mechanistically to persistent Akt signaling. Finally, we found that disruption of TexPSR-associated chaperones in CD8+ T cells improved cancer immunotherapy preclinically and demonstrated that high TexPSR feature in T cells in cancer patients confers poor response to immunotherapy clinically. Our findings collectively highlight TexPSR as a hallmark and a mechanistic driver of T cell exhaustion, raising the possibility of targeting proteostasis as a potential novel approach for cancer immunotherapy.

Project description:Although understanding of T-cell exhaustion is widely based on mouse models, its analysis in cancer patients could provide clues indicating tumor sensitivity to immune checkpoint blockade (ICB). Data suggests a role for costimulatory pathways, particularly CD28, in exhausted T-cell responsiveness to PD-1/PD-L1 blockade. Here, we used single-cell transcriptomic, phenotypic, and functional approaches to dissect the relation between CD8+ T-cell exhaustion, CD28 costimulation, and tumor specificity in head and neck, cervical, and ovarian cancers. We found that memory tumor-specific CD8+ T cells, but not bystander cells, sequentially express immune checkpoints once they infiltrate tumors leading, in situ, to a functionally exhausted population. Exhausted T cells were nonetheless endowed with effector and tumor residency potential but exhibited loss of the costimulatory receptor CD28 in comparison to their circulating memory counterparts. Accordingly, PD-1 inhibition improved proliferation of circulating tumor-specific CD8 T cells and reversed functional exhaustion of specific T cells at tumor sites. In agreement with their tumor specificity, high infiltration of tumors by exhausted cells was predictive of response to therapy and survival in ICB-treated head and neck cancer patients. Our results showed that PD-1 blockade–mediated proliferation/reinvigoration of circulating memory T cells and local reversion of exhaustion occur concurrently to control tumors.

Project description:Chronic infections and cancers induce CD8+ T cell exhaustion, but within this exhausted CD8+ T cell pool, a self-renewing, stem-like subset known as progenitor CD8+ T (TPRO) cells play a crucial role in maintaining long-term immunity. These TPRO cells exhibit stem-like characteristics, including quiescence, multipotency, and self-renewal, which are the cardinal features of memory T cells. However, the mechanisms that preserve their stem-like properties under chronic antigen stimulation remain unclear. In this study, we identified that SATB1 as a shared feature is highly expressed in both TPRO and memory CD8+ T cells. While the role of SATB1 in stem-like CD8+ T cells remains unknown, its function as epigenetic regulator in promoting quiescence in hematopoietic stem cells led us to hypothesize that SATB1 plays a pivotal role in regulating the stemness of TPRO and memory CD8+ T cells. To test this hypothesis, we employed CRISPR-mediated gene editing to delete Satb1 gene specifically in CD8+ T cells. Upon chronic LCMV infection, we found that SATB1-deficient CD8+ T cells failed to maintain TPRO subset with enhanced transition towards terminally differentiated cells. Similarly, the SATB1 deficiency in acute viral infection impaired the formation of memory CD8+ T cells. Mechanistically, our multi-omic assays revealed that SATB1 regulates the chromatin accessibility and transcriptional activities of stemness-associated genes, such asTcf7, Bach2,andMyb. Overall, our results underscore the critical role of SATB1 in maintaining the transcriptional and epigenetic features of stem-like CD8+ T cells, shedding light on the previously unappreciated regulatory mechanisms that sustain the stemness of antigen-specific CD8+ T cells.

Project description:Chronic infections and cancers induce CD8+ T cell exhaustion, but within this exhausted CD8+ T cell pool, a self-renewing, stem-like subset known as progenitor CD8+ T (TPRO) cells play a crucial role in maintaining long-term immunity. These TPRO cells exhibit stem-like characteristics, including quiescence, multipotency, and self-renewal, which are the cardinal features of memory T cells. However, the mechanisms that preserve their stem-like properties under chronic antigen stimulation remain unclear. In this study, we identified that SATB1 as a shared feature is highly expressed in both TPRO and memory CD8+ T cells. While the role of SATB1 in stem-like CD8+ T cells remains unknown, its function as epigenetic regulator in promoting quiescence in hematopoietic stem cells led us to hypothesize that SATB1 plays a pivotal role in regulating the stemness of TPRO and memory CD8+ T cells. To test this hypothesis, we employed CRISPR-mediated gene editing to delete Satb1 gene specifically in CD8+ T cells. Upon chronic LCMV infection, we found that SATB1-deficient CD8+ T cells failed to maintain TPRO subset with enhanced transition towards terminally differentiated cells. Similarly, the SATB1 deficiency in acute viral infection impaired the formation of memory CD8+ T cells. Mechanistically, our multi-omic assays revealed that SATB1 regulates the chromatin accessibility and transcriptional activities of stemness-associated genes, such asTcf7, Bach2,andMyb. Overall, our results underscore the critical role of SATB1 in maintaining the transcriptional and epigenetic features of stem-like CD8+ T cells, shedding light on the previously unappreciated regulatory mechanisms that sustain the stemness of antigen-specific CD8+ T cells.

Project description:Chronic infections and cancers induce CD8+ T cell exhaustion, but within this exhausted CD8+ T cell pool, a self-renewing, stem-like subset known as progenitor CD8+ T (TPRO) cells play a crucial role in maintaining long-term immunity. These TPRO cells exhibit stem-like characteristics, including quiescence, multipotency, and self-renewal, which are the cardinal features of memory T cells. However, the mechanisms that preserve their stem-like properties under chronic antigen stimulation remain unclear. In this study, we identified that SATB1 as a shared feature is highly expressed in both TPRO and memory CD8+ T cells. While the role of SATB1 in stem-like CD8+ T cells remains unknown, its function as epigenetic regulator in promoting quiescence in hematopoietic stem cells led us to hypothesize that SATB1 plays a pivotal role in regulating the stemness of TPRO and memory CD8+ T cells. To test this hypothesis, we employed CRISPR-mediated gene editing to delete Satb1 gene specifically in CD8+ T cells. Upon chronic LCMV infection, we found that SATB1-deficient CD8+ T cells failed to maintain TPRO subset with enhanced transition towards terminally differentiated cells. Similarly, the SATB1 deficiency in acute viral infection impaired the formation of memory CD8+ T cells. Mechanistically, our multi-omic assays revealed that SATB1 regulates the chromatin accessibility and transcriptional activities of stemness-associated genes, such asTcf7, Bach2,andMyb. Overall, our results underscore the critical role of SATB1 in maintaining the transcriptional and epigenetic features of stem-like CD8+ T cells, shedding light on the previously unappreciated regulatory mechanisms that sustain the stemness of antigen-specific CD8+ T cells.

Project description:Blocking PD-1 can reinvigorate exhausted CD8 T cells (TEX) and improve control of chronic infections and cancer. One potential advantage of this immunotherapy is durable protection if immune memory can be established. It is unclear, however, whether blocking PD-1 can reprogram TEX into effector (TEFF) or durable memory T cells (TMEM). Here, we found reinvigoration of TEX by PD-L1 blockade caused re-acquisition of some features of TEFF, but minimal memory development. We used microarray analysis to profile exhausted cells from anti-PD-L1 mice after two weeks of treatment to study if PD-L1 blockade caused re-acquistion of some feature of effector or memory cells.