The type I antifreeze protein gene family in Pleuronectidae

Antifreeze proteins (AFPs) protect marine teleosts from freezing in icy seawater by binding to nascent ice crystals and preventing their growth. It has been suggested that the gene dosage for AFPs in fish reflects the degree of exposure to harsh winter climates. The starry flounder, _Platichthys stellatus_, has been chosen to examine this relationship because it inhabits a range of the Pacific coast from California to the Arctic. This flatfish is presumed to produce type I AFP, which is an alanine-rich, amphipathic alpha-helix. Genomic DNA from four starry flounder was Southern blotted and probed with a cDNA of a winter flounder liver AFP. The hybridization signal was consistent with a gene family of approximately 40 copies. Blots of DNA from other starry flounder indicate that California fish have far fewer gene copies whereas Alaska fish have far more. This analysis is complicated by the fact that there are three different type I AFP isoforms. The first is expressed in the liver and secreted into circulation, the second is a larger hyperactive dimer also thought to be expressed in the liver, and the third is expressed in peripheral tissues. To evaluate the contribution of these latter two isoforms to the overall gene signal on Southern blots, hybridization probes for the three isoforms were isolated from starry flounder DNA by genomic cloning. Two clones revealed linkage of genes for different isoforms, and this was confirmed by genomic Southern blotting, where hybridization patterns indicated that the majority of genes were present in tandem repeats. The sequence and diversity of all three isoforms was sampled in the starry flounder genome by PCR. All coding sequences derived for the skin and liver isoforms were consistent with the proposed structure-function relationships for this AFP, where the flat hydrophobic side of the helix is conserved for ice binding. There was greater sequence diversity in the skin and hyperactive isoforms than in the liver isoform, suggesting that the latter evolved recently from one of the other two. The genomic PCR primers are currently being used to sample isoform diversity in related right-eyed flounders to test this hypothesis.

An immune modulatory role for the fes proto-oncogene

The Fes protein tyrosine kinase is abundantly expressed in phagocytic immune cells, including tumor associated macrophages. Fes knockout mice (fes-/-) display enhanced sensitivity to LPS, and this was shown to be associated with increased NF-κB signaling and TNFα production from fes-/- macrophages. Interestingly, tumor onset in the mouse mammary tumor virus (MMTV-Neu) transgenic mouse model of breast cancer is significantly delayed in fes-/- mice, and this was associated with increased frequency of CD11b+ myeloid and CD3+ T cells in the premalignant mammary glands. Recent studies have also implicated Fes in cross-talk between MHC-I and the NF-κB and IRF-3 pathways in macrophages. Signal 3, the production of inflammatory cytokines and Type I interferons downstream of NF-κB and IRF-3 pathways in antigen presenting cells, is considered an important component of T-cell activation, after engagement of T cell receptor by MHC presented antigen (Signal 1) and co-receptors by their ligands (Signal 2). Using a lymphocytic choriomeningitis virus (LCMV) model of immune activation, I show that LPS stimulated fes-/- macrophages promote more robust activation of LCMV antigenspecific CD8+ T cells than wild type macrophages (fes+/+). Furthermore, LPS stimulated fes-/- macrophages showed increased phosphorylation of NF-B and IRF-3. I also showed that Fes colocalizes with MHC-I in dynamic vesicular structures within macrophages. These observations are consistent with a model where Fes regulates Signal 3 in antigen presenting cells through roles in cross-talk between MHC-I and the NF-kB and IRF-3 signaling pathways. This suggests that Fes plays an immune checkpoint role at the level of Signal 3, and that Fes inhibition could promote tumor immunity through increased Signal 3 driven T cell activation.

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.

THE IMPACT OF VIRUS INFECTION IN DEREGULATION OF CYTOKINE PRODUCTION UPON SECONDARY BACTERIAL INFECTION

Dendritic cells (DCs) secrete cytokines such as interleukin-23 (IL-23) when stimulated with certain Toll-like receptor (TLR) agonists and infected with pathogens such as P. aeruginosa. IL- 23 is a proinflammatory cytokine that plays a critical role in the proliferation and differentiation of the IL-17 producing Th17- CD4 T helper cells. The lack of efficient cytokine production from antigen-presenting cells, such as DCs, can impact CD4 differentiation and thus impair the immune responses against pathogens. Clearance of some bacterial infections, such as Klebsiella pneumonia and Listeria monocytogenes has been shown to be dependent on the induction of IL-23 and therefore, deregulation of these cytokines as a direct result of virus infection may impede immune responses to secondary infections. Here, an inhibition of TLR ligand or P. aeruginosa-induced IL- 23 expression in Lymphocytic Choriomeningitis Virus (LCMV)-infected bone marrow-derived dendritic cells (BMDCs) has been demonstrated, indicating that an important function of these cells is disrupted during virus/bacterial coinfection. While production of TNF-α was unaffected in LPS stimulated cells, TNF-α was significantly inhibited in bacterium infected cells by LCMV. Type I IFN in LPS or LCMV infected cell was not detected and therefore, ruling out the possibility of cytokine suppression by Type I IFN. The production of IL-10 was high in BMDCs infected with LCMV and stimulated with LPS or bacteria. Analysis of multiple cytokines produced in this coinfection model demonstrated that LCMV infection impacts specific cytokine production upon LPS or bacterium infection, which may be important for bacterial clearance. This data is important for future immunotherapy use in viral/bacterial coinfection scenarios.