Transcriptional and Epigenetic Regulation of Human CD4+ T Helper Lineage Specification

Activated T helper (Th) cells have ability to differentiate into functionally distinct Th1, Th2 and Th17 subsets through a series of overlapping networks that include signaling and transcriptional control and the epigenetic mechanisms to direct immune responses. However, inappropriate execution in the differentiation process and abnormal function of these Th cells can lead to the development of several immune mediated diseases. Therefore, the thesis aimed at identifying genes and gene regulatory mechanisms responsible for Th17 differentiation and to study epigenetic changes associated with early stage of Th1/Th2 cell differentiation. Genome wide transcriptional profiling during early stages of human Th17 cell differentiation demonstrated differential regulation of several novel and currently known genes associated with Th17 differentiation. Selected candidate genes were further validated at protein level and their specificity for Th17 as compared to other T helper subsets was analyzed. Moreover, combination of RNA interference-mediated downregulation of gene expression, genome-wide transcriptome profiling and chromatin immunoprecipitation followed by massive parallel sequencing (ChIP-seq), combined with computational data integration lead to the identification of direct and indirect target genes of STAT3, which is a pivotal upstream transcription factor for Th17 cell polarization. Results indicated that STAT3 directly regulates the expression of several genes that are known to play a role in activation, differentiation, proliferation, and survival of Th17 cells. These results provide a basis for constructing a network regulating gene expression during early human Th17 differentiation. Th1 and Th2 lineage specific enhancers were identified from genome-wide maps of histone modifications generated from the cells differentiating towards Th1 and Th2 lineages at 72h. Further analysis of lineage-specific enhancers revealed known and novel transcription factors that potentially control lineage-specific gene expression. Finally, we found an overlap of a subset of enhancers with SNPs associated with autoimmune diseases through GWASs suggesting a potential role for enhancer elements in the disease development. In conclusion, the results obtained have extended our knowledge of Th differentiation and provided new mechanistic insights into dysregulation of Th cell differentiation in human immune mediated diseases.

The expression of HLA-B27 modulates intracellular signaling in human monocytic macrophages

Reactive arthritis (ReA) is an inflammatory joint disease triggered by certain bacterial infections e.g. gastroenteritis caused by Salmonella. ReA is strongly associated to HLA-B27. However, the mechanism behind this association is unknown but it is suggested that the bacteria or bacterial compartments persist in the body. In this study, it was investigated whether the intracellular signaling is altered in HLA-B27- transfected U937 monocytic macrophages. Moreover, the contribution of HLA–B27 heavy chain (HC) misfolding was of interest. The study revealed that p38 activity plays a crucial role in controlling intracellular Salmonella Enteritidis in U937 cells. The replication of intracellular bacteria was dependent on p38 kinase and the activity of p38 was dysregulated in HLA-B27- transfected cells expressing misfolding heavy chains (HCs). Also the double-stranded RNA -dependent kinase (PKR) that modifies p38 signaling was overexpressed and hypophosphorylated upon infection and lipopolysaccharide stimulation. The expression of CCAAT enhancer binding protein beta (C/EBPβ) was found to be increased after infection and stimulation. Increased amount of full length human antigen R (HuR), disturbed HuR cleavage and reduced dependence on PKR after infection were observed. All the findings were linked to HLA-B27 HCs containing misfoldingassociated glutamic acid 45 (Glu45) at the peptide binding groove. The results indicate that the expression of HLA-B27 modulates the intracellular environment of U937 monocytic macrophages by altering signaling. This phenomenon is at least partially associated to the HLA-B27 misfolding. These observations offer a novel explanation how HLA-B27 may modulate inflammatory response induced by ReA-triggering bacteria.