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In the recent years, myxobacteria have emerged as a novel source of natural compounds with structural diversity and biological activity for drug discovery. In this work, the two myxobacterial compounds archazolid and vioprolide were characterized for their potential pharmacological effects in vascular endothelial cells. Archazolid is a wellestablished v-ATPase inhibitor found in Archangium gephyra and Cystobacter spec. As the v-ATPase represents a promising target in cancer treatment, the effects of archazolid have been intensively studied in cancer cells, but rarely in endothelial cells. Vioprolide is an antifungal and cytotoxic metabolite obtained from Cystobacter violaceus. There are only few studies on vioprolide, most of them focusing on its biosynthesis. Preliminary studies revealed that it inhibited TNF-induced expression of ICAM-1, indicating possible anti-inflammatory properties. As the endothelium plays an important role in cancer and inflammation, it represents an attractive drug target. Therefore, the archazolid and vioprolide were investigated regarding their effects on endothelial cells.
V-ATPase inhibition by archazolid resulted in anti-tumor and anti-metastatic effects in vitro and in vivo. Archazolid was used to study the consequences of v-ATPase inhibition in endothelial cells that might contribute to the anti-metastatic activities observed in vivo. To analyze the impact of archazolid on the interaction endothelial and cancer cells, in vitro cell adhesion and transmigration assays were performed using primary HUVEC or immortalized HMEC-1 and different cancer cell types (MDA-MB-231, PC-3 and Jurkat cells). For these experiments, only the endothelial cells were treated with archazolid. VATPase inhibition by archazolid led to an increased adhesion of the metastatic breast cancer cell line MDA-MB-231 and prostate cancer cell line PC-3 onto endothelial cells whereas the adhesion of Jurkat cells was unaffected. Interestingly, archazolid treatment of HUVECs decreased the transendothelial migration of MDA-MB-231 cells. Endothelial ICAM-1, VCAM-1, E-selectin and N-cadherin are potential ligands of interacting cancer cells. Therefore, the mRNA and surface protein levels of these cell adhesion molecules were measured via qRT-PCR and flow cytometry, respectively. These adhesion molecules were not responsible for the archazolid-induced cancer cell adhesion, as archazolid treatment of HUVECs did not upregulate their mRNA or surface expression. Instead, cell adhesion assays using a monoclonal antibody against integrin subunit β1 showed that β1-integrins expressed on MDA-MB-231 and PC-3 cells mediated the archazolid-induced cancer cell adhesion. Cell adhesion assays onto plastic coated with ECM components which are the major ligands of β1-integrins, revealed that MDA-MB231 and PC-3 cells preferably interact with collagen. So next, we investigated the influence of archazolid on surface collagen levels in HUVECs by immunostaining, which demonstrated an increase of nearly 50 % upon archazolid treatment. We confirmed the hypothesis that the expression and activity of cathepsin B, a lysosomal enzyme that degrades extracellular matrix components including collagen, was inhibited by archazolid in endothelial cells. Finally, overexpression of cathepsin B reduced the cancer cell adhesion on archazolid-treated HUVECs, but also in control cells, indicating a negative correlation between cathepsin B expression and cancer cell adhesion.
The influence of vioprolide on the interaction of endothelial cells with leukocytes was analyzed by in vitro cell adhesion assays using HUVECs and primary monocytes, THP-1 or Jurkat cells. Vioprolide inhibited the adhesion of these cells onto TNF-activated HUVECs. In addition, the endothelial-leukocyte interaction was observed in vivo by intravital microscopy in the mouse cremaster muscle. Vioprolide prevented the TNFinduced firm adhesion and transmigration of leukocytes, while leukocyte rolling was not affected. ICAM-1, VCAM-1 and E-selectin are cell adhesion molecules, which are upregulated by TNF and mediate leukocyte adhesion onto endothelial cells. Therefore, flow cytometric analysis was performed to measure their surface expression. Vioprolide significantly decreased TNF-induced expression of surface ICAM-1, VCAM-1 and E-selectin, which was in line with the in vitro results. In vivo, vioprolide may act in a different way on E-selectin expression, so that leukocyte rolling, which is governed by E-selectin, remained unaffected. qRT-PCR experiments revealed that the mRNA expression of ICAM-1 and VCAM-1 were also reduced by vioprolide, indicating a regulation on transcriptional level. In contrast, the mRNA expression of E-selectin was not decreased at the timepoint when surface protein expression was diminished. The induction of these cell adhesion molecules is mainly mediated by the transcription factor NFκB. A Dual-Luciferase® reporter assay was used to study the impact of vioprolide on the TNF-induced NFκB promotor activity. Vioprolide blocked the TNF-induced NFκB promotor activity while the TNF-induced IκBα degradation and nuclear translocation of the NFκB subunit p65 was not altered by vioprolide. Western blot analysis revealed that vioprolide had no effect on the activation of MAPK (p38, JNK) and AKT by TNF, which could interfere with the NFκB-dependent gene expression.
Taken together, archazolid and vioprolide are interesting myxobacterial compounds with different modes of actions. The study suggests that the v-ATPase inhibitor archazolid impairs the expression and activity of cathepsin B in endothelial cells, which leads to a higher amount of collagen on the endothelial surface. As a result, the adhesion of β1-integrin expressing metastatic cancer cells onto archazolid-treated endothelial cells increased while transendothelial migration was reduced. Further, archazolid represents a promising tool to elucidate the role of v-ATPase in endothelial cells. Vioprolide was able to prevent TNF-induced endothelial-leukocyte interaction in vitro and in vivo by interfering with NFκB-dependent gene expression. Further research is required to enlighten the underlying mechanism and the direct target of vioprolide.
The three major autoimmune diseases (ADs) of the liver are primary biliary cholangitis (PBC), primary sclerosing cholangitis (PSC), and autoimmune hepatitis (AIH). All of those diseases show an aggressive immune reaction resulting in the destruction of liver tissue and finally to the development of hepatic fibrosis.
PSC is an autoimmune mediated disease of unknown etiology. It is characterized by inflammation of intra- and extrahepatic bile ducts. The progressive destruction of the bile ducts can lead to liver cirrhosis and finally to liver failure. Clinical signs for PSC are increased alkaline phosphatase (AP) and gamma glutamyltransferase (GGT) levels, presence of perinuclear anti-neutrophil cytoplasmic antibodies (pANCA) and bile ducts with characteristic strictures and dilations of the biliary tree as well as onion skin fibrosis surrounding the damaged bile ducts. Currently, there is no established treatment for PSC patients. The administration of ursodeoxycholic acid (UDCA) is being use as a therapy. However, it merely serves a symptomatic treatment to reduce serum AP and GGT as well as the formation of gallstones. In the advanced stage of PSC, liver transplantation is the last therapeutic option. Mdr2-/- mice are an excepted mouse model for human PSC. Such mice show lymphocytes infiltration into the liver, bile duct lesions, as well as the presence of the typical onion skin-like pericholangitis and periductal fibrosis.
AIH is a rare chronic autoimmune disease of the liver that results from the loss of self-tolerance to hepatocytes and leads to destruction of the hepatic parenchyma with the onset of cirrhosis. Clinical signs for AIH are elevated alanine aminotransferase (ALT) and aspartate transaminase (AST) levels, hypergammaglobulinemia and different types of autoantibodies. In addition, interphase hepatitis with lymphocytic and plasmacellular infiltrates in the periportal field are characteristic for AIH. Two different subtypes of AIH exist and depending on their autoantibody profile they can be distinguished into AIH type 1 which is characterized by the presence of anti-nuclear (ANA) and/or anti-smooth muscular (SMA) autoantibodies, and AIH type 2 showing liver/kidney microsomal autoantibodies (LKM-1). LKM-1 recognizes the major autoantigen, the 2D6 isoform of the cytochrome P450 enzyme family (CYP2D6). One mouse model for AIH is the CYP2D6 model in which the injection of Ad-2D6 leads to a breakdown of the immune tolerance by the destruction of hepatocytes.
There are some patients with autoimmune diseases of the liver who have both cholestatic and hepatic liver enzymes and histological features suggestive of two different liver diseases. These patients are diagnosed with an overlap syndrome (OS).
In my thesis I generated an animal model with characteristics of both diseases, which would mimic features of human PSC-AIH OS. Mdr2-/- mice which spontaneously develop PSC were infected with Ad-2D6 to trigger the autoimmune-driven hepatic injury. Pathogenesis of PSC-AIH OS mice was compared to mice with solitary PSC or AIH. Naïve FVB wild type mice have been used as healthy controls. The characterization of the PSC-AIH OS model was done by analyzing serological parameters like ALT, AP, different antibodies like pANCA, LKM-1 like CYP2D6 and total IgG. Additionally, fibrosis and cholangitis were analyzed by immunohistochemistry and Western blotting. Moreover, cellular infiltrations of CD4+ and CD8+ T cells, dendritic cells (DCs), monocytes/macrophages and neutrophils were determined with immunohistochemistry. Finally, the overall immune balance in the liver and the frequency of CYP specific T cells were analyzed via flow cytometry. Our new mouse model indeed represents the characteristics of both PSC and AIH and mimics features of the human PSC-AIH OS. It allows studying the development of a PSC-AIH OS and how the two overlapping diseases are influencing one another. In a second approach I wanted to induce CYP2D6-specific tolerance in AIH mice. Therefore, I tried four different approaches, namely intranasal peptide administration, injection of tolerogenic DCs, antigen-coupled splenocytes, and Ag-coupled nanoparticles (NP) and evaluated their potential to induce CYP2D6 specific Treg with the capacity to prevent AIH in mice. Unfortunately, the intranasal peptide administration and also the injection of tolerogenic DCs did not increase the amount of CYP2D6 specific Treg which would lead to a reduction of the frequency of inflammatory T cells. Surprisingly, the injection of antigen-coupled splenocytes showed the opposite effect characterized by a very strong cytokine secretion in the tolerized mice. The use of NPs led to an increase in CYP2D6 specific Treg as well as in decrease in the frequency of inflammatory T cells and finally has the potential for a therapeutic approach.
In summary, the generated PSC-AIH OS model represents many clinical signs which can also be observed in PSC-AIH OS patients. This model can be used to study the etiology of this overlap syndrome and further to test potential therapeutic approaches. The different immune tolerance induction pathways which I tried in the AIH model show that NPs have to potential to induce immune tolerance but this approach has to be refined and the outcome has to be characterized in more detail.