Project description:To investigate gene expression changes associated with stimulation of TCRs of different affinity, primary CD8 T cells were transduced with sequence optimized TCRs of various affinities and stimulated for 6h. Gene expression was measured at baseline (0h) and after 6h after stimulation with low dose NY-ESO-1 multimer

Project description:RATIONALE: The Epstein Barr virus can cause cancer and lymphoproliferative disorders. Ganciclovir is an antiviral drug that acts against the Epstein Barr virus. Arginine butyrate may make virus cells more sensitive to ganciclovir. Combining ganciclovir and arginine butyrate may kill more Epstein Barr virus cells and tumor cells. PURPOSE: Phase I trial to study the effectiveness of arginine butyrate plus ganciclovir in treating patients who have cancer or lymphoproliferative disorders that are associated with the Epstein Barr virus.

Project description:Clonotype selection of T cell receptors (TCRs) have been the core component of TCR therapy development. However, the conventional and widely used major histocompatibility complex (MHC) multimer staining technologies focus on high-affinity interactions between TCR and MHC-antigen complex, which may fail to identify TCRs with high efficacy for activating T cells. Here, we developed the Aptamer-based T Lymphocyte Activity Screening and sequencing (ATLAS-seq) method on a microfluidic platform. ATLAS-seq isolates and characterizes activated T cells using an aptamer-based fluorescent molecular sensor to monitor cytokine secretion from single-T cells upon antigen stimulation, followed by single-cell sequencing. As a proof of principle study, we used ATLAS-seq to screen cytomegalovirus (CMV)-reactive TCRs and identified a distinct clonotype population with a higher T cell activation level compared to one recovered by Dextramer staining method. Furthermore, we observed that ATLAS-seq selected TCR clonotypes are more efficient in target cell killing than those from Dextramer staining. Therefore, our ATLAS-seq can provide an efficient workflow to screen highly reactive antigen-specific TCR clonotypes for cancer immunotherapy.

Project description:Purpose: Using RNA-sequencing, determine the effect of corticosteroids on human airway smooth muscle cells (ASM) exposed to Th1 and/or Th17 cytokines. Effects of cytokines and/or corticosteroids on gene expression was assessed. Methods: Pediatric human ASM (ages 0-21; n=4/treatment group) were serum starved for 48 h and then treated with 10 ng/mL TNFα, IFNγ, IL-17A, TNFα/IFNγ, or IFNγ/IL-17A in the presence of vehicle (0.01% DMSO) or 10 nM fluticasone propionate (FP). Cells were harvested after 18 h for RNA isolation, QC, library prep, and RNA sequencing on the Illumina HiSeq4000 platform. RNA quality and integrity was determined by gel electrophoresis and Agilent 2100 Bioanalyzer. Following sequencing. FASTQ files were processed and analyzed to generate counts files and perform differential expression analysis. Results: Our analyses show that cytokines, particularly TNFα, IFNγ, and TNFα/IFNγ had significant effects on gene expression. Differentially expressed genes were largely related to pro-inflammatory responses. Interestingly, we found that IL-17A had only modest effects on gene expression. Corticosteroids (FP) reduced or inhibited the effects of pro-inflammatory cytokines. However, these anti-inflammatory effects were reduced in cells treated with TNFα/IFNγ or IL-17A/IFNγ. Conclusions: These studies highlight the differential effects of pro-inflammatory cytokines and corticosteroids on gene expression in human ASM.

Project description:Epstein-Barr virus has been reported to regulate cellular microRNA expression in B cells. In the present study, we investigated the differential microRNAs modulated by Epstein-Barr virus in Naspharyngeal Carcinoma, using CapitalBio corporation's mammalian miRNA arrays. Three cellular models were used in this study: the human naspharyngeal carcinoma cell line TW03 as a blank control; TW03 transfected with Epstein-Barr virus encoded LMP1; TW03 transfected with Epstein-Barr virus encoded LMP2A

Project description:Here, we investigated the time-course changes in the pattern of microRNA (miRNA) expression of TNFα and IFNγ-stimulated and unstimulated hCMEC/D3 cells, an immortalized human cerebral microvascular endothelial cell line. In order to investigate pro-inflammatory cytokine-induced changes in miRNA levels in hCMEC/D3 cells, we challenged brain endothelial cells with TNFα and IFNγ (100 ng/ml) for 2 h, 6 h and 24 h and determined microRNA expression in cytokine-stimulated and unstimulated cells

Project description:Compare Epstein-Barr-positive and Epstein-Barr-negative Burkitt lymphoma cases forboth cellular and viral microRNA expression profile, and to assess the role of viralmicroRNAs in Burkitt lymphomagenesis

Project description:TNFα and IFNg are two inflammatory cytokines that play critical roles in immune responses, but they can also negatively affect cell proliferation and viability. In particular, the combination of the two cytokines (TNFα/IFNγ) synergistically causes death in many cell types. We recently demonstrated that, mouse embryonic stem cells (ESCs) isolated from the inner cell mass of the blastocyst stage embryo, do not respond to TNFα and IFNg, thereby avoiding TNFα/IFNγ cytotoxicity. This study expanded our investigation to mouse trophoblast stem cells (TSCs) and differentiated trophoblasts (TSC-TBs), the major cellular constituents in trophectoderm of the blastocyst. We report here that TNFα or IFNγ alone has limited negative effect on the viability of mouse fibroblasts, but TNFα/IFNγ effectively kill these cells. However, TSCs and TSC-TBs are markedly resistant to the cytotoxicity of TNFα/IFNγ. With molecular and cellular approaches and transcriptomic analysis, we demonstrated that TSCs and TSC-TBs have attenuated responses to TNFα and IFNγ and the underlying molecular mechanisms that allow these cells to avoid the synergistic cytotoxicity of TNFα/IFNγ. Together with our previous findings in ESCs, we propose that the attenuated responses of TSCs, TSC-TBs, and ESCs to TNFα and IFNγ may serve as a protective mechanism that limits cytokine cytotoxicity in the blastocyst.

Project description:Gene expression analysis in Epstein-Barr virus negative DLBCL samples obtained from patients with Richter syndrome, lymphocytes from CLL patients and epstein-Barr virus positive DLBCL cell lines derived after CLL tumors xenotransplantation

Project description:Many cytokines are involved in the pathogenesis of autoimmune diseases and are recognized as relevant therapeutic targets to attenuate inflammation, such as TNFα in RA and IFNα/γ in SLE. To relate the transcriptional imprinting of cytokines in a cell type-specific and disease-specific manner, we generated gene-expression profiles from peripheral monocytes of SLE and RA patients and compared them to in vitro-generated signatures induced by TNFα, IFNα2a and IFNγ. Monocytes from SLE and RA patients revealed disease-specific gene-expression profiles. In vitro-generated signatures induced by IFNα2a and IFNγ showed similar profiles that only partially overlapped with those induced by TNFα. Comparisons between disease-specific and in vitro-generated signatures identified cytokine-regulated genes in SLE and RA with qualitative and quantitative differences. The IFN-responses in SLE and RA were found to be regulated in a STAT1-dependent and STAT1-independent manner, respectively. Similarly, genes recognized as TNFα-regulated were clearly distinguishable between RA and SLE patients. While the activity of SLE monocytes was mainly driven by IFN, the activity from RA monocytes showed a dominance of TNFα that was characterized by STAT1 down-regulation. The responses to specific cytokines were revealed to be disease-dependent and reflected the interplay of cytokines within various inflammatory milieus. This study has demonstrated that monocytes from RA and SLE patients exhibit disease-specific gene-expression profiles, which can be molecularly dissected when compared to in vitro-generated cytokine signatures. The results suggest that an assessment of cytokine-response status in monocytes may be helpful for improvement of diagnosis and selection of the best cytokine target for therapeutic intervention. Expression profiles of human peripheral blood monocytes activated in vivo and stimulated in vitro. Monocytes from patients with SLE and RA and from healthy donors were used for generating disease-specific gene-expression profiles, where these profiles represent in vivo activation of monocytes. In addition, monocytes from healthy donors were stimulated in vitro by cytokines: TNFα, IFNα2a and IFNγ. Cytokine-specific gene-expression profiles were generated by comparing stimulated monocytes with unstimulated ones. TNFα-, IFNα2a- and IFNγ as cytokine-specific gene-expression profiles were compared with RA and SLE, as disease-specific gene-expression profiles.