Project description:As “effector” cells, B lymphocytes make antibodies. They also regulate immune functions through ligand-receptor interactions. The limited understanding of regulatory roles of B cells prompted us to develop a workflow that profiles B cell ligand and receptor expression, maps in silico interactions involving ligands with high “specificity scores”, validates the function of top ligand-receptor interactions, and unveils transcription regulation of specific ligands. Using this unbiased approach, here we report the regulatory functions of a new subset of murine B cells that express BATF3 as a hallmark transcription factor. BATF3+ B cells, as generated upon B cell activation by innate TLR and adaptive CD40 and IL-21 receptor signals, lose their effector cell function (making class-switched antibodies) while expressing new ligands, most notably cytokine IL-27 and chemokine CXCL10. As elicited by viral infection and immunization, IL-27+CXCL10+ B cells target effector B cells through the IL-27 receptor and, together with IFNg, optimize the antibody response and anti-viral immunity. Also appearing in tumors and retained there through the autocrine CXCL10-CXCR3 interaction, they enhance B cell expression of immune checkpoint PD-L1 and suppress anti-tumor immunity. Thus, we have identified new regulatory B cells and provided a paradigmatic framework to investigate immune cell communications.

Project description:As “effector” cells, B lymphocytes make antibodies. They also regulate immune functions through ligand-receptor interactions. The limited understanding of regulatory roles of B cells prompted us to develop a workflow that profiles B cell ligand and receptor expression, maps in silico interactions involving ligands with high “specificity scores”, validates the function of top ligand-receptor interactions, and unveils transcription regulation of specific ligands. Using this unbiased approach, here we report the regulatory functions of a new subset of murine B cells that express BATF3 as a hallmark transcription factor. BATF3+ B cells, as generated upon B cell activation by innate TLR and adaptive CD40 and IL-21 receptor signals, lose their effector cell function (making class-switched antibodies) while expressing new ligands, most notably cytokine IL-27 and chemokine CXCL10. As elicited by viral infection and immunization, IL-27+CXCL10+ B cells target effector B cells through the IL-27 receptor and, together with IFNg, optimize the antibody response and anti-viral immunity. Also appearing in tumors and retained there through the autocrine CXCL10-CXCR3 interaction, they enhance B cell expression of immune checkpoint PD-L1 and suppress anti-tumor immunity. Thus, we have identified new regulatory B cells and provided a paradigmatic framework to investigate immune cell communications.

Project description:As “effector” cells, B lymphocytes make antibodies. They also regulate immune functions through ligand-receptor interactions. The limited understanding of regulatory roles of B cells prompted us to develop a workflow that profiles B cell ligand and receptor expression, maps in silico interactions involving ligands with high “specificity scores”, validates the function of top ligand-receptor interactions, and unveils transcription regulation of specific ligands. Using this unbiased approach, here we report the regulatory functions of a new subset of murine B cells that express BATF3 as a hallmark transcription factor. BATF3+ B cells, as generated upon B cell activation by innate TLR and adaptive CD40 and IL-21 receptor signals, lose their effector cell function (making class-switched antibodies) while expressing new ligands, most notably cytokine IL-27 and chemokine CXCL10. As elicited by viral infection and immunization, IL-27+CXCL10+ B cells target effector B cells through the IL-27 receptor and, together with IFNg, optimize the antibody response and anti-viral immunity. Also appearing in tumors and retained there through the autocrine CXCL10-CXCR3 interaction, they enhance B cell expression of immune checkpoint PD-L1 and suppress anti-tumor immunity. Thus, we have identified new regulatory B cells and provided a paradigmatic framework to investigate immune cell communications.

Project description:As “effector” cells, B lymphocytes make antibodies. They also regulate immune functions through ligand-receptor interactions. The limited understanding of regulatory roles of B cells prompted us to develop a workflow that profiles B cell ligand and receptor expression, maps in silico interactions involving ligands with high “specificity scores”, validates the function of top ligand-receptor interactions, and unveils transcription regulation of specific ligands. Using this unbiased approach, here we report the regulatory functions of a new subset of murine B cells that express BATF3 as a hallmark transcription factor. BATF3+ B cells, as generated upon B cell activation by innate TLR and adaptive CD40 and IL-21 receptor signals, lose their effector cell function (making class-switched antibodies) while expressing new ligands, most notably cytokine IL-27 and chemokine CXCL10. As elicited by viral infection and immunization, IL-27+CXCL10+ B cells target effector B cells through the IL-27 receptor and, together with IFNg, optimize the antibody response and anti-viral immunity. Also appearing in tumors and retained there through the autocrine CXCL10-CXCR3 interaction, they enhance B cell expression of immune checkpoint PD-L1 and suppress anti-tumor immunity. Thus, we have identified new regulatory B cells and provided a paradigmatic framework to investigate immune cell communications.

Project description:As “effector” cells, B lymphocytes make antibodies. They also regulate immune functions through ligand-receptor interactions. The limited understanding of regulatory roles of B cells prompted us to develop a workflow that profiles B cell ligand and receptor expression, maps in silico interactions involving ligands with high “specificity scores”, validates the function of top ligand-receptor interactions, and unveils transcription regulation of specific ligands. Using this unbiased approach, here we report the regulatory functions of a new subset of murine B cells that express BATF3 as a hallmark transcription factor. BATF3+ B cells, as generated upon B cell activation by innate TLR and adaptive CD40 and IL-21 receptor signals, lose their effector cell function (making class-switched antibodies) while expressing new ligands, most notably cytokine IL-27 and chemokine CXCL10. As elicited by viral infection and immunization, IL-27+CXCL10+ B cells target effector B cells through the IL-27 receptor and, together with IFNg, optimize the antibody response and anti-viral immunity. Also appearing in tumors and retained there through the autocrine CXCL10-CXCR3 interaction, they enhance B cell expression of immune checkpoint PD-L1 and suppress anti-tumor immunity. Thus, we have identified new regulatory B cells and provided a paradigmatic framework to investigate immune cell communications.

Project description:As “effector” cells, B lymphocytes make antibodies. They also regulate immune functions through ligand-receptor interactions. The limited understanding of regulatory roles of B cells prompted us to develop a workflow that profiles B cell ligand and receptor expression, maps in silico interactions involving ligands with high “specificity scores”, validates the function of top ligand-receptor interactions, and unveils transcription regulation of specific ligands. Using this unbiased approach, here we report the regulatory functions of a new subset of murine B cells that express BATF3 as a hallmark transcription factor. BATF3+ B cells, as generated upon B cell activation by innate TLR and adaptive CD40 and IL-21 receptor signals, lose their effector cell function (making class-switched antibodies) while expressing new ligands, most notably cytokine IL-27 and chemokine CXCL10. As elicited by viral infection and immunization, IL-27+CXCL10+ B cells target effector B cells through the IL-27 receptor and, together with IFNg, optimize the antibody response and anti-viral immunity. Also appearing in tumors and retained there through the autocrine CXCL10-CXCR3 interaction, they enhance B cell expression of immune checkpoint PD-L1 and suppress anti-tumor immunity. Thus, we have identified new regulatory B cells and provided a paradigmatic framework to investigate immune cell communications.

Project description:As “effector” cells, B lymphocytes make antibodies. They also regulate immune functions through ligand-receptor interactions. The limited understanding of regulatory roles of B cells prompted us to develop a workflow that profiles B cell ligand and receptor expression, maps in silico interactions involving ligands with high “specificity scores”, validates the function of top ligand-receptor interactions, and unveils transcription regulation of specific ligands. Using this unbiased approach, here we report the regulatory functions of a new subset of murine B cells that express BATF3 as a hallmark transcription factor. BATF3+ B cells, as generated upon B cell activation by innate TLR and adaptive CD40 and IL-21 receptor signals, lose their effector cell function (making class-switched antibodies) while expressing new ligands, most notably cytokine IL-27 and chemokine CXCL10. As elicited by viral infection and immunization, IL-27+CXCL10+ B cells target effector B cells through the IL-27 receptor and, together with IFNg, optimize the antibody response and anti-viral immunity. Also appearing in tumors and retained there through the autocrine CXCL10-CXCR3 interaction, they enhance B cell expression of immune checkpoint PD-L1 and suppress anti-tumor immunity. Thus, we have identified new regulatory B cells and provided a paradigmatic framework to investigate immune cell communications.

Project description:As “effector” cells, B lymphocytes make antibodies. They also regulate immune functions through ligand-receptor interactions. The limited understanding of regulatory roles of B cells prompted us to develop a workflow that profiles B cell ligand and receptor expression, maps in silico interactions involving ligands with high “specificity scores”, validates the function of top ligand-receptor interactions, and unveils transcription regulation of specific ligands. Using this unbiased approach, here we report the regulatory functions of a new subset of murine B cells that express BATF3 as a hallmark transcription factor. BATF3+ B cells, as generated upon B cell activation by innate TLR and adaptive CD40 and IL-21 receptor signals, lose their effector cell function (making class-switched antibodies) while expressing new ligands, most notably cytokine IL-27 and chemokine CXCL10. As elicited by viral infection and immunization, IL-27+CXCL10+ B cells target effector B cells through the IL-27 receptor and, together with IFNg, optimize the antibody response and anti-viral immunity. Also appearing in tumors and retained there through the autocrine CXCL10-CXCR3 interaction, they enhance B cell expression of immune checkpoint PD-L1 and suppress anti-tumor immunity. Thus, we have identified new regulatory B cells and provided a paradigmatic framework to investigate immune cell communications.

Project description:The inhibitory receptor Tim-3 has emerged as a critical regulator of the T cell dysfunction that develops in chronic viral infections and cancers. However, little is known regarding the signaling pathways that drive Tim-3 expression. Here, we demonstrate that IL-27 induces NFIL3, which promotes permissive chromatin remodeling of the Tim-3 locus and induces Tim-3 expression together with the immunosuppressive cytokine IL-10. We further show that the IL-27/NFIL3 signaling axis is crucial for the induction of Tim-3 in vivo. IL-27-conditioned Th1 cells exhibit reduced effector function and are poor mediators of intestinal inflammation. This inhibitory effect is NFIL3 dependent. In contrast, tumor-infiltrating lymphocytes (TILs) from IL-27R-/- mice exhibit reduced NFIL3, less Tim-3 expression and failure to develop dysfunctional phenotype, resulting in better tumor growth control. Thus, our data identify an IL-27/NFIL3 signaling axis as a key regulator of effector T cell responses via induction of Tim-3, IL-10, and T cell dysfunction. Through gene expression profile analysis, we identified a series of transcription factors that are induced by IL-27. Particularly, the induction of NFIL3 is highly relevant to Tim-3 expression. Naïve CD4+ T cells from C57BL/6 mice were stimulated with plate-bound anti-CD3 and anti-CD28 antibodies for 60 hours. The cells were subjected to gene profile analysis. A comparative transcriptome analysis between cells under neutral culture condition (Untreated) and cells treated with IL-27 (IL-27-treated) was peformed to screen transcription factors that are induced by IL-27 signaling.

Project description:Here we implemented a simple dendritic cell (DC)-mediated immunization approach to study the effects of commonly used adjuvants, Toll like receptor (TLR) ligands, on effector CD8 T cell differentiation and memory T cell development. To our surprise, we found that the TLR4 ligand LPS was far more superior to other TLR ligands in generating memory CD8 T cells upon immunization. LPS boosted clonal expansion similar to the other adjuvants, but fewer of the activated CD8 T cells died during contraction, generating a larger pool of memory cells. Intriguingly, monophosphoryl lipid A (MPLA), another TLR4 ligand, enhanced clonal expansion of effector CD8 T cells, but also promoted their terminal differentiation and contraction; thus, fewer memory CD8 T cells formed and MPLA-primed animals were less protected against secondary infection compared to those primed with LPS. Furthermore, gene expression profiling revealed that LPS-primed effector cells displayed a stronger pro-memory gene expression signature, whereas the gene expression profile of MPLA-primed effector cells had aligned closer with terminal effector CD8 T cells. Mice that contain small number of P14 CD8 T cells were immunized with DC-33 either alone or in combination with LPS or MPLA. KLRG1loIL-7Rhi MPECs were purified by FACS sort, and mRNA isolated from MPECs was subjected to whole-genome expression profiling using Illumina MouseWG-6 v2.0 Expression BeadChip.