During inflammatory responses, macrophages make and secrete cytokines, including the proinflammatory cytokine TNF-alpha (TNF). TNF is a highly potent activator of immune responses with pleiomorphic effects throughout the body. TNF is a key causative agent of chronic inflammatory diseases and is of an intense clinical interest as a therapeutic target. At the outset of this thesis, little was known about how macrophages secrete TNF. Notably, the pathways, carriers and molecules that regulate TNF secretion had not been characterised. A main goal of this work was to identify compartment and molecules involved in the intracellular trafficking of TNF. Live cell imaging of GFP-TNF was established and this provided novel and important new insights into trafficking. Both endogenous and GFP-tagged TNF were followed in macrophages using fluorescence microscopy. The trafficking of other molecules in macrophages was also studied. The major findings of this work include the identification of a new two-step secretory pathway for TNF and other proteins from the trans-Golgi Network (TGN) to the cell surface. This pathway goes via the recycling endosome as an intermediate station. Pleiotrophic tubular-vesicular carriers containing TNF bud off the TGN for the post-Golgi trafficking of TNF and their characterization both in live cell imaging and in biochemical analysis of isolated vesicles constituted the main parts of this work. Functional studies, including endosome inactivation and overexpression of Rab11 mutants (proteins functioning at the level of the recycling endosome) revealed that recycling endosomes have indeed an essential role in the exocytic trafficking of TNF in macrophages. This thesis also provides further insight into recycling endosomes as a possible intermediate step in the exocytic trafficking of several other proteins including the adhesion protein E-Cadherin, that function at the cell surface. Finally, the last chapter of this thesis examines endocytic pathways in activated macrophages. Assays for fluid phase endocytosis and receptor-mediated endocytosis were established and the regulation of both pathways was compared. The results show that LPS has opposite effects on fluid phase and receptor mediated endocytosis, decreasing and increasing their activity respectively. Recycling of transferrin through the recycling endosome was also measured, providing a link with studies on TNF exocytosis. Overall, the work in this thesis has made a major contribution to our understanding of TNF trafficking in macrophages, of macrophage pathways more generally and of trafficking at a fundamental level. The findings herein set the stage for more in depth analysis at a single molecular level to explore TNF regulation in normal and disease cells.
| Identifer | oai:union.ndltd.org:ADTP/254021 |
| Creators | Daniele Sangermani |
| Source Sets | Australiasian Digital Theses Program |
| Detected Language | English |
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