Project description:The CD4+ T cells expressing cytolytic molecules such as granzymes and perforins have been detected in many diseases and are shown to be enriched in the effector memory expressing CD45RA (TEMRA) in humans, but their origin remains elusive. However, their gene expression profile in comparison to classically defined cytotoxic T lymphocytes (CTLs), the CD8-CTLs has not been well demonstrated, hence their relevance remains debatable. Thus in this study by parallelly analysing the CD4-CTLs and CD8-CTLs, we demonstrate that they are indistinguishable for the cytolytic program with both showing similar gene expression profile and T cell antigen-receptor (TCR) clonal expansion. Further using an integrative multi-omics approach combining the transcriptome, TCR repertoire, and open chromatin profile of CD4+ naïve (CD4-TN) and memory subsets, we discovered a stem-cell memory subset that is pre-committed to CTL program within the CD4+ T cell lineage. Through an in vitro differentiation model we developed CD4+ T cells with cytolytic potential from CD4-TN cells. The in vitro differentiated cells followed the trajectory of different developmental memory subsets from ex vivo CD4+ T cells for transcriptomic patterns as well as open-chromatin landscape. Thus, through this model, we deciphered the molecular signatures of early commitment of CD4-TN cells to cytotoxicity program. Of particular interest was the expression of both longevity as well as cytotoxicity associated gene sets by the in vitro differentiated CD4-CTLs, hence generating long-lived CD4-CTL effectors. This specific property can be further explored for vaccine development as well as testing the efficacy and cell based therapies for precision medicine.

Project description:The CD4+ T cells expressing cytolytic molecules such as granzymes and perforins have been detected in many diseases and are shown to be enriched in the effector memory expressing CD45RA (TEMRA) in humans, but their origin remains elusive. However, their gene expression profile in comparison to classically defined cytotoxic T lymphocytes (CTLs), the CD8-CTLs has not been well demonstrated, hence their relevance remains debatable. Thus in this study by parallelly analysing the CD4-CTLs and CD8-CTLs, we demonstrate that they are indistinguishable for the cytolytic program with both showing similar gene expression profile and T cell antigen-receptor (TCR) clonal expansion. Further using an integrative multi-omics approach combining the transcriptome, TCR repertoire, and open chromatin profile of CD4+ naïve (CD4-TN) and memory subsets, we discovered a stem-cell memory subset that is pre-committed to CTL program within the CD4+ T cell lineage. Through an in vitro differentiation model we developed CD4+ T cells with cytolytic potential from CD4-TN cells. The in vitro differentiated cells followed the trajectory of different developmental memory subsets from ex vivo CD4+ T cells for transcriptomic patterns as well as open-chromatin landscape. Thus, through this model, we deciphered the molecular signatures of early commitment of CD4-TN cells to cytotoxicity program. Of particular interest was the expression of both longevity as well as cytotoxicity associated gene sets by the in vitro differentiated CD4-CTLs, hence generating long-lived CD4-CTL effectors. This specific property can be further explored for vaccine development as well as testing the efficacy and cell based therapies for precision medicine.

Project description:The CD4+ T cells expressing cytolytic molecules such as granzymes and perforins have been detected in many diseases and are shown to be enriched in the effector memory expressing CD45RA (TEMRA) in humans, but their origin remains elusive. However, their gene expression profile in comparison to classically defined cytotoxic T lymphocytes (CTLs), the CD8-CTLs has not been well demonstrated, hence their relevance remains debatable. Thus in this study by parallelly analysing the CD4-CTLs and CD8-CTLs, we demonstrate that they are indistinguishable for the cytolytic program with both showing similar gene expression profile and T cell antigen-receptor (TCR) clonal expansion. Further using an integrative multi-omics approach combining the transcriptome, TCR repertoire, and open chromatin profile of CD4+ naïve (CD4-TN) and memory subsets, we discovered a stem-cell memory subset that is pre-committed to CTL program within the CD4+ T cell lineage. Through an in vitro differentiation model we developed CD4+ T cells with cytolytic potential from CD4-TN cells. The in vitro differentiated cells followed the trajectory of different developmental memory subsets from ex vivo CD4+ T cells for transcriptomic patterns as well as open-chromatin landscape. Thus, through this model, we deciphered the molecular signatures of early commitment of CD4-TN cells to cytotoxicity program. Of particular interest was the expression of both longevity as well as cytotoxicity associated gene sets by the in vitro differentiated CD4-CTLs, hence generating long-lived CD4-CTL effectors. This specific property can be further explored for vaccine development as well as testing the efficacy and cell based therapies for precision medicine.

Project description:The CD4+ T cells expressing cytolytic molecules such as granzymes and perforins have been detected in many diseases and are shown to be enriched in the effector memory expressing CD45RA (TEMRA) in humans, but their origin remains elusive. However, their gene expression profile in comparison to classically defined cytotoxic T lymphocytes (CTLs), the CD8-CTLs has not been well demonstrated, hence their relevance remains debatable. Thus in this study by parallelly analysing the CD4-CTLs and CD8-CTLs, we demonstrate that they are indistinguishable for the cytolytic program with both showing similar gene expression profile and T cell antigen-receptor (TCR) clonal expansion. Further using an integrative multi-omics approach combining the transcriptome, TCR repertoire, and open chromatin profile of CD4+ naïve (CD4-TN) and memory subsets, we discovered a stem-cell memory subset that is pre-committed to CTL program within the CD4+ T cell lineage. Through an in vitro differentiation model we developed CD4+ T cells with cytolytic potential from CD4-TN cells. The in vitro differentiated cells followed the trajectory of different developmental memory subsets from ex vivo CD4+ T cells for transcriptomic patterns as well as open-chromatin landscape. Thus, through this model, we deciphered the molecular signatures of early commitment of CD4-TN cells to cytotoxicity program. Of particular interest was the expression of both longevity as well as cytotoxicity associated gene sets by the in vitro differentiated CD4-CTLs, hence generating long-lived CD4-CTL effectors. This specific property can be further explored for vaccine development as well as testing the efficacy and cell based therapies for precision medicine.

Project description:The CD4+ T cells expressing cytolytic molecules such as granzymes and perforins have been detected in many diseases and are shown to be enriched in the effector memory expressing CD45RA (TEMRA) in humans, but their origin remains elusive. However, their gene expression profile in comparison to classically defined cytotoxic T lymphocytes (CTLs), the CD8-CTLs has not been well demonstrated, hence their relevance remains debatable. Thus in this study by parallelly analysing the CD4-CTLs and CD8-CTLs, we demonstrate that they are indistinguishable for the cytolytic program with both showing similar gene expression profile and T cell antigen-receptor (TCR) clonal expansion. Further using an integrative multi-omics approach combining the transcriptome, TCR repertoire, and open chromatin profile of CD4+ naïve (CD4-TN) and memory subsets, we discovered a stem-cell memory subset that is pre-committed to CTL program within the CD4+ T cell lineage. Through an in vitro differentiation model we developed CD4+ T cells with cytolytic potential from CD4-TN cells. The in vitro differentiated cells followed the trajectory of different developmental memory subsets from ex vivo CD4+ T cells for transcriptomic patterns as well as open-chromatin landscape. Thus, through this model, we deciphered the molecular signatures of early commitment of CD4-TN cells to cytotoxicity program. Of particular interest was the expression of both longevity as well as cytotoxicity associated gene sets by the in vitro differentiated CD4-CTLs, hence generating long-lived CD4-CTL effectors. This specific property can be further explored for vaccine development as well as testing the efficacy and cell based therapies for precision medicine.

Project description:The CD4+ T cells expressing cytolytic molecules such as granzymes and perforins have been detected in many diseases and are shown to be enriched in the effector memory expressing CD45RA (TEMRA) in humans, but their origin remains elusive. However, their gene expression profile in comparison to classically defined cytotoxic T lymphocytes (CTLs), the CD8-CTLs has not been well demonstrated, hence their relevance remains debatable. Thus in this study by parallelly analysing the CD4-CTLs and CD8-CTLs, we demonstrate that they are indistinguishable for the cytolytic program with both showing similar gene expression profile and T cell antigen-receptor (TCR) clonal expansion. Further using an integrative multi-omics approach combining the transcriptome, TCR repertoire, and open chromatin profile of CD4+ naïve (CD4-TN) and memory subsets, we discovered a stem-cell memory subset that is pre-committed to CTL program within the CD4+ T cell lineage. Through an in vitro differentiation model we developed CD4+ T cells with cytolytic potential from CD4-TN cells. The in vitro differentiated cells followed the trajectory of different developmental memory subsets from ex vivo CD4+ T cells for transcriptomic patterns as well as open-chromatin landscape. Thus, through this model, we deciphered the molecular signatures of early commitment of CD4-TN cells to cytotoxicity program. Of particular interest was the expression of both longevity as well as cytotoxicity associated gene sets by the in vitro differentiated CD4-CTLs, hence generating long-lived CD4-CTL effectors. This specific property can be further explored for vaccine development as well as testing the efficacy and cell based therapies for precision medicine.

Project description:The CD4+ T cells expressing cytolytic molecules such as granzymes and perforins have been detected in many diseases and are shown to be enriched in the effector memory expressing CD45RA (TEMRA) in humans, but their origin remains elusive. However, their gene expression profile in comparison to classically defined cytotoxic T lymphocytes (CTLs), the CD8-CTLs has not been well demonstrated, hence their relevance remains debatable. Thus in this study by parallelly analysing the CD4-CTLs and CD8-CTLs, we demonstrate that they are indistinguishable for the cytolytic program with both showing similar gene expression profile and T cell antigen-receptor (TCR) clonal expansion. Further using an integrative multi-omics approach combining the transcriptome, TCR repertoire, and open chromatin profile of CD4+ naïve (CD4-TN) and memory subsets, we discovered a stem-cell memory subset that is pre-committed to CTL program within the CD4+ T cell lineage. Through an in vitro differentiation model we developed CD4+ T cells with cytolytic potential from CD4-TN cells. The in vitro differentiated cells followed the trajectory of different developmental memory subsets from ex vivo CD4+ T cells for transcriptomic patterns as well as open-chromatin landscape. Thus, through this model, we deciphered the molecular signatures of early commitment of CD4-TN cells to cytotoxicity program. Of particular interest was the expression of both longevity as well as cytotoxicity associated gene sets by the in vitro differentiated CD4-CTLs, hence generating long-lived CD4-CTL effectors. This specific property can be further explored for vaccine development as well as testing the efficacy and cell based therapies for precision medicine.

Project description:Bach2 codes for a transcriptional regulator exerting major influences on T cell mediated immune regulation. Effector CTLs derived from in vitro activation of murine CD8+ T cells showed increased proliferative and cytolytic capacity in the absence of BACH2. Before activation, BACH2-deficient CD8+ T cells had a higher abundance of memory and reduced abundance of naïve cells compared to wild-type. CTLs derived from central memory T cells were more potently cytotoxic than those derived from naïve T cells, but even within separated subsets, BACH2-deficiency conferred a cytotoxic advantage. Immunofluorescence and electron microscopy revealed larger granules in BACH2-deficient compared to wild-type CTLs, and proteomic analysis showed an increase in granule content, including perforin and granzymes. Thus, the enhanced cytotoxicity observed in effector CTLs lacking BACH2 arises not only from differences in their initial differentiation state but also inherent production of enlarged cytolytic granules. These results demonstrate how a single gene deletion can produce a CTL super-killer.

Project description:Acquisition of effector properties is a key step in the generation of cytotoxic T lymphocytes (CTLs). Here we show that inflammatory signals regulate Dicer expression in CTL, and that deletion or depletion of Dicer in mouse or human activated CD8+ T cells causes upregulation of perforin, granzyme and effector cytokines. Genome-wide analysis of miRNA changes induced by exposure of differentiating CTLs to IL-2 and inflammatory signals identifies miR-139 and miR-150 as components of a miRNA network that controls perforin, eomesodermin (Eomes) and IL-2Ra expression in differentiating CTLs and whose activity is modulated by IL-2, inflammation and antigenic stimulation. Overall our data show that strong IL-2R and inflammatory signals act through Dicer and miRNAs to control the cytolytic program and other aspects of effector CTL differentiation. Comparison of control and Dicer knock-out CTLs differentiated in vitro; Comparison of wild type CTLs differentiated in vitro with or without inflammatory stimuli; Comparison of effector and memory precursor CTLs isolated from mice infected with LCMV-Armstrong

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.