Project description:CD28-driven “signal 2” is critical for naïve CD8+ T cell responses to dendritic cell (DC)-presented weak antigens, including non-mutated tumor-associated antigens (TAAs). However, it is unclear how DC-primed cytotoxic T lymphocytes (CTLs) respond to the same TAAs presented by cancer cells which lack CD28 ligands. Here, we show that NK receptors (NKRs) DNAM-1 and NKG2D replace CD28 during CTL re-activation by cancer cells presenting low levels of MHC I/TAA complexes, leading to enhanced proximal TCR signaling, immune synapse formation, CTL polyfunctionality, release of cytolytic granules and antigen-specific cancer cell killing. Double-transduction of T cells with recombinant TCR and NKR constructs or upregulation of NKR-ligand expression on cancer cells by chemotherapy enabled effective recognition and killing of poorly immunogenic tumor cells by CTLs. Operational synergy between TCR and NKRs in CTL recognition explains the ability of cancer-expressed self-antigens to serve as tumor rejection antigens, helping to develop more effective therapies.

Project description:Recent work in immunometabolism has emphasised the role of mitochondria in both the innate and adaptive immune system. Mitochondria are important in T cell development and differentiation, but less is known about their role in CD8+ effector T cells (CTLs). We found that CTLs that lack the mitochondrial deubiquitinase USP30 undergo promiscuous mitophagy, destroying most of the cellular mitochondria. Surprisingly, this results in a markedly diminished killing capacity, while motility, signalling and secretion remain intact. This study uses quantitative DIA proteomics to measure the impact of USP30 deficiency on the global proteome of IL-2 maintained, 4.5 h TCR retriggered and 4.5 h TCR retriggered + cycloheximide CTL. We also measured the impact of pharmacologically inhibiting mitochondrial translation by performing Quantitative DIA proteomics on IL2 maintained or TCR retriggered CTL treated with the mitochondrial translation inhibitor doxycycline for 4.5 hrs. Unexpectedly, inhibition of mitochondrial translation, through genetic or pharmacologic methods, was the mechanism by which CTL killing was impaired. Reduced mitochondrial translation triggered attenuated cytosolic translation which precluded replenishment of secreted effector molecules thereby limiting the capacity of CTLs to serially kill multiple targets. Thus, mitochondria emerge as a previously unappreciated homeostatic regulator of protein translation required for serial CTL killing.

Project description:The present study reports an unbiased analysis of the cytotoxic T cell serine-threonine phosphoproteome using high resolution mass spectrometry. Approximately 2,000 phosphorylations were identified in CTLs of which approximately 450 were controlled by TCR signaling. A significantly overrepresented group of molecules identified in the phosphoproteomic screen were transcription activators, co-repressors and chromatin regulators. A focus on the chromatin regulators revealed that CTLs have high expression of the histone deacetylase HDAC7 but continually phosphorylate and export this transcriptional repressor from the nucleus. HDAC7 dephosphorylation results in its nuclear accumulation and suppressed expression of genes encoding key cytokines, cytokine receptors and adhesion molecules that determine CTL function. The screening of the CTL phosphoproteome thus reveals intrinsic pathways of serine-threonine phosphorylation that target chromatin regulators in CTLs and determine the CTL functional program. We used Affymetrix microarray analysis to explore the molecular basis for the role of HDAC7 in CTLs and the impact of GFP-HDAC7 phosphorylation deficient mutant expression on the CTL transcriptional profile. In vitro generated P14 TCR cytotoxic T cells were retrovirally infected with a construct encoding GFP-HDAC7 phosphorylation deficient mutant, sorted in base of GFP expression (GFP positive and GFP negative) and processed for microarray analysis in three biological replicas.

Project description:Recent work in immunometabolism has emphasised the role of mitochondria in both the innate and adaptive immune system. Mitochondria are important in T cell development and differentiation, but less is known about their role in CD8+ effector T cells (CTLs). We found that CTLs that lack the mitochondrial deubiquitinase USP30 undergo promiscuous mitophagy, destroying most of the cellular mitochondria. Surprisingly, this results in a markedly diminished killing capacity, while motility, signalling and secretion remain intact. This study uses quantitative DIA proteomics to measure the impact of USP30 deficiency on the global proteome of IL-2 maintained, 4.5 h TCR retriggered and 4.5 h TCR retriggered + cycloheximide CTL. Unexpectedly, inhibition of mitochondrial translation, through genetic or pharmacologic methods, was the mechanism by which CTL killing was impaired. Reduced mitochondrial translation triggered attenuated cytosolic translation which precluded replenishment of secreted effector molecules thereby limiting the capacity of CTLs to serially kill multiple targets. Thus, mitochondria emerge as a previously unappreciated homeostatic regulator of protein translation required for serial CTL killing.

Project description:Effector cytotoxic T lymphocytes (CTLs) are critical for ridding the body of infected or cancerous cells. Recognition of an antigenic ligand by the CTL’s T cell receptor (TCR) triggers a signalling cascade that ultimately results in the targeted release of cytolytic granules and/or secretion of cytokines and chemokines to alert and recruit additional immune cells. These signalling cascades are capable of initiating transcription, translation, and cytoskeletal rearrangements. While previous work has demonstrated how translation and intracellular reorganisation contribute to CTL effector responses, the role of transcription is less well studied. To address this, we examined the impact of blocking transcription on the CTL proteome during TCR stimulation. These data demonstrated a strong transcriptional requirement for expression of cytokines and chemokines but not cytolytic molecules. Together with functional studies, these data reveal differential molecular control of the cell-cell communication and cytolytic functions of effector CTLs. CTLs exhibit complete and persistent priming for cytolytic activity prior to target cell encounter, but they require de novo transcription to recruit additional immune cells that amplify the response.

Project description:The present study reports an unbiased analysis of the cytotoxic T cell serine-threonine phosphoproteome using high resolution mass spectrometry. Approximately 2,000 phosphorylations were identified in CTLs of which approximately 450 were controlled by TCR signaling. A significantly overrepresented group of molecules identified in the phosphoproteomic screen were transcription activators, co-repressors and chromatin regulators. A focus on the chromatin regulators revealed that CTLs have high expression of the histone deacetylase HDAC7 but continually phosphorylate and export this transcriptional repressor from the nucleus. HDAC7 dephosphorylation results in its nuclear accumulation and suppressed expression of genes encoding key cytokines, cytokine receptors and adhesion molecules that determine CTL function. The screening of the CTL phosphoproteome thus reveals intrinsic pathways of serine-threonine phosphorylation that target chromatin regulators in CTLs and determine the CTL functional program. We used Affymetrix microarray analysis to explore the molecular basis for the role of HDAC7 in CTLs and the impact of GFP-HDAC7 phosphorylation deficient mutant expression on the CTL transcriptional profile.

Project description:Transcriptional profiling of mouse tumor-specific cytotoxic T lymphocytes (CTL) comparing activation-induced gene expression profiles induced by tumor-specific antigen (Ag) and CD3 mAb. CTLs were stimulated with either Ag or CD3 mAb for 3 and 24 h, respectively. The stimulated CTLs were compared to un-stimulated CTLs. The objective was to identify differential gene expression profiles induced by the two activation (Ag vs CD3 mAb) conditions. Two-condition experiments, un-stimulated vs stimulated CTLs. Biological replicates: 3 replicates for each comparison. Unstimulated CTLs were compared to stimulated CTLs (Ag and CD3 mAb, respectively).

Project description:CD4+ cytotoxic T lymphocytes (CD4-CTLs) have been reported to play a protective role in several viral infections. However, little is known in humans about the biology of CD4-CTL generation, their functional properties, heterogeneity and clonal diversity, especially in relation to other well-described CD4+ memory T cell subsets. We performed single-cell RNA-seq in over 9000 cells to unravel CD4-CTL heterogeneity, transcriptional profile and clonality in humans. The single-cell differential gene expression analysis, revealed a spectrum of known transcripts, including several linked to cytotoxic and co-stimulatory function, and transcripts of unknown cytotoxicity-related function that are expressed at higher levels in the TEMRA subset, which is highly enriched for CD4-CTLs, compared to cells in the central and effector memory subsets (TCM, TEM). Simultaneous T cells antigen receptor (TCR) analysis in single-cells and bulk subsets revealed that CD4-TEMRA cells show marked clonal expansion compared to TCM and TEM cells and that the majority of CD4-TEMRA were dengue virus (DENV)-specific in subjects with previous DENV infection. The profile of CD4-TEMRA was highly heterogeneous across subjects, with four distinct clusters identified by the single-cell analysis. Most importantly, we identified distinct clusters of CD4-CTL effector and precursor cells in the TEMRA subset; the precursor cells shared TCR clonotypes with CD4-CTL effectors and were distinguished by high expression of the interleukin-7 receptor. Our identification of a CD4-CTL precursor population may allow further investigation of how CD4-CTLs arise in humans and thus could provide insights into the mechanisms that may be utilized to generate durable and effective CD4-CTL immunity.

Project description:CD4+ cytotoxic T lymphocytes (CD4-CTLs) have been reported to play a protective role in several viral infections. However, little is known in humans about the biology of CD4-CTL generation, their functional properties, heterogeneity and clonal diversity, especially in relation to other well-described CD4+ memory T cell subsets. We performed single-cell RNA-seq in over 9000 cells to unravel CD4-CTL heterogeneity, transcriptional profile and clonality in humans. The single-cell differential gene expression analysis, revealed a spectrum of known transcripts, including several linked to cytotoxic and co-stimulatory function, and transcripts of unknown cytotoxicity-related function that are expressed at higher levels in the TEMRA subset, which is highly enriched for CD4-CTLs, compared to cells in the central and effector memory subsets (TCM, TEM). Simultaneous T cells antigen receptor (TCR) analysis in single-cells and bulk subsets revealed that CD4-TEMRA cells show marked clonal expansion compared to TCM and TEM cells and that the majority of CD4-TEMRA were dengue virus (DENV)-specific in subjects with previous DENV infection. The profile of CD4-TEMRA was highly heterogeneous across subjects, with four distinct clusters identified by the single-cell analysis. Most importantly, we identified distinct clusters of CD4-CTL effector and precursor cells in the TEMRA subset; the precursor cells shared TCR clonotypes with CD4-CTL effectors and were distinguished by high expression of the interleukin-7 receptor. Our identification of a CD4-CTL precursor population may allow further investigation of how CD4-CTLs arise in humans and thus could provide insights into the mechanisms that may be utilized to generate durable and effective CD4-CTL immunity.

Project description:CD4+ cytotoxic T lymphocytes (CD4-CTLs) have been reported to play a protective role in several viral infections. However, little is known in humans about the biology of CD4-CTL generation, their functional properties, heterogeneity and clonal diversity, especially in relation to other well-described CD4+ memory T cell subsets. We performed single-cell RNA-seq in over 9000 cells to unravel CD4-CTL heterogeneity, transcriptional profile and clonality in humans. The single-cell differential gene expression analysis, revealed a spectrum of known transcripts, including several linked to cytotoxic and co-stimulatory function, and transcripts of unknown cytotoxicity-related function that are expressed at higher levels in the TEMRA subset, which is highly enriched for CD4-CTLs, compared to cells in the central and effector memory subsets (TCM, TEM). Simultaneous T cells antigen receptor (TCR) analysis in single-cells and bulk subsets revealed that CD4-TEMRA cells show marked clonal expansion compared to TCM and TEM cells and that the majority of CD4-TEMRA were dengue virus (DENV)-specific in subjects with previous DENV infection. The profile of CD4-TEMRA was highly heterogeneous across subjects, with four distinct clusters identified by the single-cell analysis. Most importantly, we identified distinct clusters of CD4-CTL effector and precursor cells in the TEMRA subset; the precursor cells shared TCR clonotypes with CD4-CTL effectors and were distinguished by high expression of the interleukin-7 receptor. Our identification of a CD4-CTL precursor population may allow further investigation of how CD4-CTLs arise in humans and thus could provide insights into the mechanisms that may be utilized to generate durable and effective CD4-CTL immunity.