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The neuronal ceroid lipofuscinoses (NCLs) are fatal neurodegenerative disorders in which the visual system is affected in early stages of disease. A typical accompanying feature is neuroinflammation, the pathogenic impact of which is presently unknown. In this study, the role of inflammatory cells in the pathogenesis was investigated in Palmitoyl-protein thioesterase 1-deficient (Ppt1-/-) and Ceroidlipofuscinosis, neuronal 3-deficient (Cln3-/-) mice, models of the infantile and juvenile forms of NCL, respectively. Focusing predominantly on the visual system, an infiltration of CD8+ cytotoxic Tlymphocytes and an activation of microglia/macrophage-like cells was observed early in disease. To analyze the pathogenic impact of lymphocytes, Ppt1-/- mice were crossbred with mice lacking lymphocytes (Rag1-/-) and axonal transport, perturbation and neuronal survival were scored. Lack of lymphocytes led to a significant amelioration of neuronal disease and reconstitution experiments revealed a crucial role of CD8+ cytotoxic T-lymphocytes. Lack of lymphocytes also caused an improved clinical phenotype and extended longevity. To investigate the impact of microglia/macrophage-like cells, Ppt1-/- and Cln3-/- mice were crossbred with mice lacking sialoadhesin (Sn-/-), a monocyte lineage-restricted cell adhesion molecule important for interactions between macrophage-like cells and lymphocytes. Similar to the lack of lymphocytes, absence of sialoadhesin significantly ameliorated the disease in Ppt1-/- and Cln3-/- mice. Taken together, both T-lymphocytes and microglia/macrophage-like cells were identified as pathogenic mediators in two distinct forms of fatal inherited neurodegenerative storage disorders. These studies expand the concept of secondary inflammation as a common pathomechanistic feature in some neurological diseases and provide novel insights that may be crucial for developing treatment strategies for different forms of NCL.
The bidirectional influence of parenchymal cells and cells of the immune system, especially of antigen-presenting and CD8\(^+\) T cells, in situations of putative auto- immune pathogenicity and degeneration was the main topic of this thesis. In the first part, the influence of human muscle cells on antigen-presenting cells was investigated. In inflammatory myopathies prominent infiltrates of immune cells containing T cells and antigen-presenting cells like macrophages and dendritic cells are present. The hypothesis was that human myoblasts have an inhibiting influence on these antigen-presenting cells under homeostatic conditions. A dysfunction or impairment under inflammatory circumstances might contribute to the development of myopathic conditions. The surface analysis of dendritic cells cocultured with myoblasts showed that immature dendritic cells could be driven into a reversible semi- mature state with significantly elevated levels of CD80. These dendritic cells were additionally characterized by their inhibiting function on T-cell proliferation. It was also shown that the lysates of healthy myoblasts could strongly enhance the phagocytic ability of macrophages, which could help with muscle regeneration and which might be disturbed in myositis patients. The second part of this thesis was about the clonal specificity of CD8\(^+\) T cells in a mouse model with genetically induced over-expression of PLP in oligodendrocytes. Here, we could show that the cytotoxic T lymphocytes, which had previously been shown to be pathogenic, were clonally expanded in the CNS of the transgenic mice. The amino acid sequences of the corresponding receptor chains were not identical, yet showed some similarities, which could mean that these clones recognize similar antigens (or epitopes of the same antigen). The knockout of PD-1 in this setting allowed for an analysis of the importance of tissue immune regulation. It became evident that the absence of PD-1 induced a larger number of clonal expansions in the CNS, hinting towards a reduced threshold for clonal disturbance and activation in these T cells. The expansions were, however, not pathogenic by themselves. Only in the presence of tissue damage and an antigenic stimulus (in our case the overexpression of PLP), the PD-1 limitation exacerbated the immune pathogenicity. Therefore, only in the presence of a “tissue damage signal”, the dyshomeostasis of T cells lacking PD-1 achieved high pathogenetic relevance. Finally, we investigated the pathogenetic role of CD8 T cells in Rasmussen encephalitis, a rare and chronic neurological disease mainly affecting children. The analysis of the T-cell receptor repertoire in Rasmussen encephalitis patients in the peripheral CD4\(^+\) and CD8\(^+\) T-cell compartments as well as the brain revealed the involvement of T cells in the pathogenicity of this disease. Many clonal expansions in the brain matched CD8\(^+\) T-cell expansions in the periphery on the sequence level. These putatively pathogenic clones could be visualized by immunohistochemistry in the brain and were found in close proximity to astrocytes and neurons. Additionally, the expanded clones could be found in the periphery of patients for at least one year.
Summary Myelin protein zero (P0) is a key myelin component in maintaining the integrity and functionality of the peripheral nervous system. Mutated variants are the cause for several disabilitating peripheral neuropathies such as Charcot-Marie-Tooth disease or Dejerine –Sotas syndrome. Using P0 knockout mice - a mouse model for these diseases - together with their wt counterparts on C57BL/6 background we studied the shaping of the T-cell repertoire specific for P0 in the presence and in the absence of this protein during the ontogeny of T-cells. Our approach was to use a series of overlapping 20-mer peptides covering the entire amino acid sequence of P0. This series of P0 peptides was employed for epitope mapping of the H2-Ab restricted T cell response. Thus, P0 peptide 5 (P0 41-60) in the extracellular domain of P0 was identified as the main immunogenic peptide. The immunogenic peptide containing the core immunodominant determinant in the P0 sequence was employed in studies of tolerance, revealing a highly reactive P0 specific T-cell repertoire in P0 ko mice while in wt mice the high avidity repertoire was inactivated in order to ensure self tolerance. In wild type and heterozygous P0 mice tolerance is not dependent on gene dosage. P0 is a tissue specific antigen whose expression is limited to myelinating Schwann cells. The classical view on tolerance to tissue specific antigens attributed this role to peripheral mechanisms. Driven by the finding that intrathymic expression of tissue-specific antigens is a common occurrence, we confirmed that “promiscuous” expression on thymic stroma holds true also for myelin P0. In addition, using bone marrow chimeras we investigated the capacity of bone marrow derived cells versus nonhematopoietic cells to induce tolerance towards P0. Our findings show that bone marrow derived cells although tolerogenic to some degree are not sufficient to mediate complete tolerance. P0 expression on cells with origin other than bone marrow showed to be sufficient and necessary to induce sound tolerance. We identified one cryptic (P0 peptide 8) and two subdominant epitopes (P0 petides 1, and 3). P0 peptide 8 was reactive in both wt and P0 ko mice. Peptides 1 and 3 were immunogenic in P0 ko but not in wt mice. Several P0 peptides including the immunogenic peptide 5 were involved in direct and adoptive transfer EAN studies. None of them induced clinical signs of EAN. Immunization with P0 peptide 3 did induce inflammation of the peripheral nerves reflected by the infiltration of macrophages and CD3 positive cells. More studies involving highly P0 specific T-cell lines are needed to characterize the P0 induced EAN. Our findings may have direct implications for secondary autoimmunity and inflammation in peripheral nerves developing after correcting the P0 genetic defect by gene therapy in aforementioned diseases.