Institut für Ernährungswissenschaften
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Publication Toll-like Receptor 9 (TLR9) activation and the innate immune response to microbial and human DNA(2023) Hsu, Emily; Fricke, Florian W.The human Toll-like Receptor 9 (TLR9) is an endosomal Pattern Recognition Receptor (PRR) that recognizes DNA sequences containing the unmethylated Cytosine-Guanine (CpG) dimers, which are present in greater abundance in most bacterial genomes compared to those of vertebrates. Specific CpG-containing sequences are strongly stimulatory of human TLR9, as shown in published studies using synthetic oligonucleotides (ODN) and DNA from bacterial species of varying genomic CpG concentration. Human TLR9 activation was experimentally examined in this thesis using DNA extracted from different bacterial sources, human DNA from Caco-2 cells, known immunostimulatory ODN, and short ODN. In vitro assays using fragment length-standardized microbial genomic DNA on HEK-Dual TLR9 Cells and human peripheral blood mononuclear cells (PBMCs) revealed that TLR9 activation strongly correlated to CpG concentration of the input DNA, with an additional influence of CpG-containing 5-mer TCGTT concentration. When DNA of varying origins and fragment lengths were used together, however, complex dynamics of TLR9 activation, co-activation, and repression were observed, which were less predictable than expected from genomic CpG concentration alone. DNase I-treated microbial DNA fragments of less than 15 bp of length were non-activating on their own, but co-activated human TLR9 together with ODN-2006 in Ramos Blue (B) cells. Similarly, human DNA fragments at the length of 50-200 bp co-activated human TLR9 with both ODN-2006 and Escherichia coli DNA in HEK-dual TLR9 cells. In contrast, large human DNA fragments at over 10000 bp of length repressed TLR9 activation by ODN-2006 in Ramos Blue cells. Finally, a preliminary study was conducted in HT-29 cells on the effect of TLR9 activation on the invasion of Fusobacterium nucleatum, an opportunistic gut pathogen with a very low genomic CpG concentration at 0.296%, using ODN-2006 and human DNA as TLR9 activators. While increased presence of intracellular Fusobacterium nucleatum upon treatment with both ODN-2006 and human DNA was noted, more studies are needed to confirm TLR9 activation as a cause of greater bacterial invasion. The human colon is the location of the largest microbial population of the human body, which provides a rich source of non-human DNA in contact with human TLR9 present in intestinal epithelial cells, plasmacytoid dendritic cells (pDCs), and B lymphocytes. Additionally, the daily mass shedding and death of human intestinal epithelial cells provide large amounts of human DNA, which when combined with microbial DNA could result in co-activation and possible autoimmunity. The thesis thus provided an in vitro model of TLR9 activation by complex DNA of varying origins and fragment lengths likely to present in the human gut environment, and prepared a working basis for future studies of TLR9 activation by human fecal metagenomic DNA.