Project description:Dendritic cells (DCs) are key initiators of the adaptive immunity, and upon recognition of pathogens are able to skew T cell differentiation to elicit appropriate responses. DCs possess this extraordinary capacity to discern external signals using receptors that recognize pathogen-associated molecular patterns. These can be glycan-binding receptors that recognize carbohydrate structures on pathogens or pathogen-associated patterns that additionally bind receptors, such as Toll-like receptors (TLRs). This study explores the early signaling events in DCs upon binding of α2-3 sialic acid (α2-3sia) that are recognized by Immune inhibitory Sialic acid binding immunoglobulin type lectins. α2-3sias are commonly found on bacteria, e.g. Group B Streptococcus, but can also be expressed by tumor cells. We investigated whether α2-3sia conjugated to a dendrimeric core alters DC signaling properties. Through phosphoproteomic analysis, we found differential signaling profiles in DCs after α2-3sia binding alone or in combination with LPS/TLR4 co-stimulation. α2-3sia was able to modulate the TLR4 signaling cascade, resulting in 109 altered phosphoproteins. These phosphoproteins were annotated to seven biological processes, including the regulation of the IL-12 cytokine pathway. Secretion of IL-10, the inhibitory regulator of IL-12 production, by DCs was found upregulated after overnight stimulation with the α2-3sia dendrimer. Analysis of kinase activity revealed altered signatures in the JAK-STAT signaling pathway. PhosphoSTAT3 (Ser727) and phosphoSTAT5A (Ser780), involved in the regulation of the IL-12 pathway, were both downregulated. Flow cytometric quantification indeed revealed de- phosphorylation over time upon stimulation with α2-3sia, but no α2-6sia. Inhibition of both STAT3 and -5A in moDCs resulted in a similar cytokine secretion profile as α-3sia triggered DCs. Conclusively, this study revealed a specific alteration of the JAK-STAT pathway in DCs upon simultaneous α2-3sia and LPS stimulation, altering the IL10:IL-12 cytokine secretion profile associated with reduction of inflammation. Targeted control of the STAT phosphorylation status is therefore an interesting lead for the abrogation of immune escape that bacteria or tumors impose on the host.

Project description:The signal transducer and activator of transcription 4 (STAT4) promotes protective immunity and autoimmunity downstream of pro-inflammatory cytokines including IL-12 and IL-23. In experimental autoimmune encephalomyelitis (EAE), an animal model of multiple sclerosis (MS), Stat4-/- mice are resistant to the development of inflammation and paralysis. Here, we examined cell-type requirements and found that in addition to T cells, STAT4 is required in dendritic cells for development of EAE. Deficiency of STAT4 in CD11c-expressing cells resulted in decreased T cell priming and inflammation in the CNS. EAE susceptibility was recovered following adoptive transfer of wild type bone marrow-derived DC to mice with STAT4-deficient DCs, but not adoptive transfer of STAT4- or IL-23R-deficient DCs. Single cell RNA-seq identified STAT4-dependent genes in DC subsets that paralleled a signature in MS patient DCs. Together, these data define a novel IL-23/DC/STAT4 pathway in DCs that could be a key to novel therapeutic targets in MS.

Project description:Analysis of the p38 MAPK pathway in regulation of dendritic cells (DCs) differentiation at the gene expression level. Bone marrow cells were cultured with mGM-CSF (20 ng/ml) in the presence of 1.5 mM of SB202190 or 0.1% DMSO. At day 7, semi-adherent cells were collected as immature DCs (iDCs). iDCs were matured by TNF-a (10 ng/ml) and IL-1b (10 ng/ml) for 48 hours. Results showed that p38 MAPK activity in DC progenitor cells acts as an antigen presentation attenuator, and disabling this critical brake during DC differentiation endows DCs with enhanced immunogenicity, which may be useful for the induction of antitumor immune responses. Total RNA was obtained from 2-day-cultured bone marrow cells, iDCs and mature DCs.

Project description:Dendritic cells (DCs) are critical in mediating immunity to pathogens, vaccines, tumors and tolerance to self. Significant progress has been made in the study of DC subsets in murine models but the translation of these findings to human DC immunobiology has not been fully realized. Murine splenic CD8+ DC and CD103+ DC possess potent antigen cross-presenting capacity. Although recent evidence points to human blood CD141+ DCs as the functional equivalent of CD8+ DC, the precise identity of the human migratory cross-presenting DC has remained elusive. We performed phenotypic and functional analyses to interrogate the DC compartment of human non-lymphoid tissues and identified three distinct subsets: i) CD141high DCs, ii) CD1c DCs and iii) CD14+ DCs. Only CD141high DCs were capable of cross-presenting soluble antigen. Comparative transcriptome analysis of steady state monocyte and DC subsets between mouse and human confirmed conservation between species, aligning the following subsets together: i) human CD141high DCs with mouse CD8+ and CD103+ DCs, ii) human CD1c+ DCs with mouse CD4+ DCs and iii) human CD14+ DC with mouse monocyte subsets. The lack of positive association between human CD1c+ DCs and mouse non-lymphoid tissue CD11b+ DCs highlights heterogeneity and predicts the existence of a monocyte-like cell within the CD11b+ DCs. Gene expression analysis using total RNA from specific human and mouse monocyte and dendritic cell subsets purified by FACS.

Project description:Dendritic cells (DCs) are critical in mediating immunity to pathogens, vaccines, tumors and tolerance to self. Significant progress has been made in the study of DC subsets in murine models but the translation of these findings to human DC immunobiology has not been fully realized. Murine splenic CD8+ DC and CD103+ DC possess potent antigen cross-presenting capacity. Although recent evidence points to human blood CD141+ DCs as the functional equivalent of CD8+ DC, the precise identity of the human migratory cross-presenting DC has remained elusive. We performed phenotypic and functional analyses to interrogate the DC compartment of human non-lymphoid tissues and identified three distinct subsets: i) CD141high DCs, ii) CD1c DCs and iii) CD14+ DCs. Only CD141high DCs were capable of cross-presenting soluble antigen. Comparative transcriptome analysis of steady state monocyte and DC subsets between mouse and human confirmed conservation between species, aligning the following subsets together: i) human CD141high DCs with mouse CD8+ and CD103+ DCs, ii) human CD1c+ DCs with mouse CD4+ DCs and iii) human CD14+ DC with mouse monocyte subsets. The lack of positive association between human CD1c+ DCs and mouse non-lymphoid tissue CD11b+ DCs highlights heterogeneity and predicts the existence of a monocyte-like cell within the CD11b+ DCs. Gene expression analysis using total RNA from specific human and mouse monocyte and dendritic cell subsets purified by FACS.

Project description:DC progenitors adapt their transcriptional program during development generating different subsets. How chromatin modifications modulate these processes is unclear. Here we investigate the impact of histone deacetylation on DCs by genetically deleting HDAC1 or HDAC2 in hematopoietic progenitors and CD11c-expressing cells. While HDAC2 isn’t critical for DC development, HDAC1 deletion impairs pro- and mature pDC generation and affects ESAM+cDC2 differentiation from tDC and pre-cDC2, whereas cDC1s are unchanged. HDAC1 knock-down in human hematopoietic cells also impairs cDC2 development highlighting its crucial role across species. Multi-omics analyses reveal that HDAC1 controls expression, chromatin accessibility and histone-acetylation of the transcription factors IRF4, IRF8 and SPIB required for efficient development of cDC2 subsets. Without HDAC1, DCs switch immunologically enhancing tumor surveillance through increased cDC1 maturation and IL-12 production driving Th1-mediated immunity and CD8+T-cell recruitment. Our study reveals the importance of histone-acetylation in DC development and anti-tumor immunity suggesting DC-targeted therapeutic strategies for immuno-oncology.

Project description:DC progenitors adapt their transcriptional program during development generating different subsets. How chromatin modifications modulate these processes is unclear. Here we investigate the impact of histone deacetylation on DCs by genetically deleting HDAC1 or HDAC2 in hematopoietic progenitors and CD11c-expressing cells. While HDAC2 isn’t critical for DC development, HDAC1 deletion impairs pro- and mature pDC generation and affects ESAM+cDC2 differentiation from tDC and pre-cDC2, whereas cDC1s are unchanged. HDAC1 knock-down in human hematopoietic cells also impairs cDC2 development highlighting its crucial role across species. Multi-omics analyses reveal that HDAC1 controls expression, chromatin accessibility and histone-acetylation of the transcription factors IRF4, IRF8 and SPIB required for efficient development of cDC2 subsets. Without HDAC1, DCs switch immunologically enhancing tumor surveillance through increased cDC1 maturation and IL-12 production driving Th1-mediated immunity and CD8+T-cell recruitment. Our study reveals the importance of histone-acetylation in DC development and anti-tumor immunity suggesting DC-targeted therapeutic strategies for immuno-oncology.

Project description:DC progenitors adapt their transcriptional program during development generating different subsets. How chromatin modifications modulate these processes is unclear. Here we investigate the impact of histone deacetylation on DCs by genetically deleting HDAC1 or HDAC2 in hematopoietic progenitors and CD11c-expressing cells. While HDAC2 isn’t critical for DC development, HDAC1 deletion impairs pro- and mature pDC generation and affects ESAM+cDC2 differentiation from tDC and pre-cDC2, whereas cDC1s are unchanged. HDAC1 knock-down in human hematopoietic cells also impairs cDC2 development highlighting its crucial role across species. Multi-omics analyses reveal that HDAC1 controls expression, chromatin accessibility and histone-acetylation of the transcription factors IRF4, IRF8 and SPIB required for efficient development of cDC2 subsets. Without HDAC1, DCs switch immunologically enhancing tumor surveillance through increased cDC1 maturation and IL-12 production driving Th1-mediated immunity and CD8+T-cell recruitment. Our study reveals the importance of histone-acetylation in DC development and anti-tumor immunity suggesting DC-targeted therapeutic strategies for immuno-oncology.

Project description:Dendritic cells (DCs) process and present self and foreign antigens to induce tolerance or immunity. In vitro models suggest that induction of immunity is controlled by regulating the presentation of antigen, but little is known about how DCs control antigen presentation in vivo. To examine antigen processing and presentation in vivo we specifically targeted antigens to the two major subsets of DCs using chimeric monoclonal antibodies. Unlike CD8+ DCs that express the cell surface protein CD205, CD8- DCs, which are positive for the 33D1 antigen, are specialized for presentation on MHC class II. This difference in antigen processing is intrinsic to the DC subsets and associated with increased expression of proteins associated with MHC processing. Experiment Overall Design: This study includes data from cell sort purified dendritic cells, B cells and CD4 and CD8 T cells. The genearray was performed to identify the transmembrane molecule recognized by the antibody 33D1. The antibody 33D1 binds specifically to CD8-CD11cHigh DCs in the spleen. Therfore the data set was reduced in this way that all molecules that are expressed either in CD8=CD11cHigh DCs, B cells and T cells were diminished of the CD8+CD11cHigh DC data set. This Genearray was also used to analyze MHC class I and MHC class II associated moelcules as the DC subsets differ in the antigen presentation. Each Series consists of 3 individuall samples

Project description:The unfolded protein response (UPR) sensor IRE1 and its target, the transcription factor XBP1s critically regulate the function of dendritic cell (DC) subtypes. However, the contribution of the IRE1/XBP1s axis in DCs to the antitumor immunity is not entirely understood. Here, using reporter mice we found that DCs, in particular type 1 conventional DCs (cDC1s), are major targets of IRE1 RNase activity in melanoma tumors. Deletion of XBP1s in CD11c+ cells resulted in augmented tumor growth, impaired effector T cell responses and decreased accumulation of TCF-1+CD8+ T cells with a precursor exhausted profile. Transcriptomic studies revealed that XBP1 deletion in tumor cDC1s induced regulated IRE1 dependent decay (RIDD) of mRNAs, which accounted for the dysregulated T cell immunity in melanoma. Thus, a strict regulatory circuit involving IRE1 RNase and XBP1s in DCs ensures optimal antitumor T cell immunity in melanoma models.