ROLE OF MULTIPLE TOLL-LIKE RECEPTOR ACTIVATION IN REGULATING CYTOTOXIC T CELL PRIMING TO LYMPOCYTIC CHORIOMENINGITIS VIRUS INFECTIONS

Foreign pathogens are recognized by toll-like receptors (TLR), present on various immune cells such as professional antigen-presenting cells (pAPCs). On recognition of its ligand, these receptors activate pAPCs, which may in turn influence naïve CD8+ T cell activation and affect their abilities to clear viral infection. However, how TLR ligands (TLR-L) can regulate CD8+ T cell responses have not been fully elucidated. This thesis will focus on examining how the presence of components from foreign pathogens, e.g. viral or bacterial infection, can contribute to shaping host immunity during concurrent viral infections. Since nitric oxide (NO), an innate effector immune molecule, was recently suggested to regulate proteasome activity; we sought to examine if NO can influence MHC-I antigen presentation during viral infections. The data in this section of the thesis provides evidence that combined TLR engagement can alter the presentation of certain CD8+ epitopes due to NO-induced inhibition in proteasome activity. Taken together, the data demonstrate that TLR ligation can influence the adaptive immune response due to induction of specific innate effector molecules such as NO. Next, the influence of combined TLR engagement on CD8+ T cell immunodominance hierarchies during viral infections was examined. In this section, we established that dual TLR2 and TLR3 stimulation alters immunodominance hierarchies of LCMV epitopes as a result of reduced uptake of cell-associated antigens and reduced cross-presentation of NP396 consequently suppressing NP396-specific CD8+ T cell responses. These findings are significant as they highlight a new role for TLR ligands in regulating anti-viral CD8+ T cell responses through impairing cross-presentation of cell-associated antigens depending on the type of TLR present in the environment during infections. Finally, we addressed TLR ligand induced type I interferon production and the signalling pathways that regulate them in two different mouse macrophage populations – those derived from the spleen or bone marrow. In this study, we observed that concomitant TLR2 stimulation blocked the induction of type I IFN induced by TLR4 in bone marrow-derived macrophages, but not spleen-derived macrophages in SOCS3-dependent manner. Taken together, the data presented in this thesis have defined new facets of how anti-viral responses are regulated by TLR activation, especially if multiple receptors are engaged simultaneously.

Functional Characterization of TAFI mutants Resistant to Activation by Thrombin, Thrombin-Thrombomodulin or Plasmin

Thrombin-activatable fibrinolysis inhibitor (TAFI) is a human plasma zymogen that acts as a molecular link between the coagulation and fibrinolytic cascades. TAFI can be activated by thrombin and plasmin but the reaction is enhanced significantly when thrombin is in a complex with the endothelial cofactor thrombomodulin (TM). The in vitro properties of TAFI have been extensively characterized. Activated TAFI (TAFIa) is a thermally unstable enzyme that attenuates fibrinolysis by catalyzing the removal of basic residues from partially degraded fibrin. The in vivo role of the TAFI pathway, however, is poorly defined and very little is known about the role of different activators in regulating the TAFI pathway. In the present study, we have constructed and characterized various TAFI mutants that are resistant to activation by specific activators. Based on peptide sequence studies, these mutants were constructed by altering key amino acid residues surrounding the scissile R92-A93 bond. We measured the thermal stabilities of all our mutants and found them to be similar to wild type TAFI. We have identified that the TAFI mutants P91S, R92K, and S90P are impaired in activation by thrombin or thrombin-TM, thrombin alone, and thrombin alone or plasmin, respectively. The TAFI mutants A93V and S94V were predicted to be resistant to activation by plasmin but this was not observed. The triple mutant, DVV was not activated by any of the aforementioned activators. Finally, we have used in vitro fibrin clot lysis assays to evaluate the antifibrinolytic potential of our variants and were able to correlate their effectiveness with their respective activation kinetics. In summary, we have developed activation resistant TAFI variants that can potentially be used to explore the role of the TAFI pathway in vivo.