Acquired Protective Immunity in Atlantic Salmon Salmo salar against the Myxozoan Kudoa thyrsites Involves Induction of MHIIß+ CD83+ Antigen-Presenting Cells.

The histozoic myxozoan parasite Kudoa thyrsites causes postmortem myoliquefaction and is responsible for economic losses to salmon aquaculture in the Pacific Northwest. Despite its importance, little is known about the host-parasite relationship, including the host response to infection. The present work sought to characterize the immune response in Atlantic salmon during infection, recovery, and reexposure to K. thyrsites After exposure to infective seawater, infected and uninfected smolts were sampled three times over 4,275 degree-days. Histological analysis revealed infection severity decreased over time in exposed fish, while in controls there was no evidence of infection. Following a secondary exposure of all fish, severity of infection in the controls was similar to that measured in exposed fish at the first sampling time but was significantly reduced in reexposed fish, suggesting the acquisition of protective immunity. Using immunohistochemistry, we detected a population of MHIIß+ cells in infected muscle that followed a pattern of abundance concordant with parasite prevalence. Infiltration of these cells into infected myocytes preceded destruction of the plasmodium and dissemination of myxospores. Dual labeling indicated a majority of these cells were CD83+/MHIIß+ Using reverse transcription-quantitative PCR, we detected significant induction of cellular effectors, including macrophage/dendritic cells (mhii/cd83/mcsf), B cells (igm/igt), and cytotoxic T cells (cd8/nkl), in the musculature of infected fish. These data support a role for cellular effectors such as antigen-presenting cells (monocyte/macrophage and dendritic cells) along with B and T cells in the acquired protective immune response of Atlantic salmon against K. thyrsites.

Cellular and humoral factors involved in the response of rainbow trout gills to Ichthyophthirius multifiliis infections: molecular and immunohistochemical studies.

The parasitic ciliate Ichthyophthirius multifiliis infecting skin, fins and gills of fish induces a protective immune response in rainbow trout (Oncorhynchus mykiss) surviving the infection and a similar protection can be conferred by i.p. injection of live theronts. A combined molecular and immunohistochemical approach has been used in this work for pinpointing cellular and humoral immune factors in gill tissue involved in the response and indicating interactions between the systemic and local responses. Fish were immunized by intra-peritoneal injection of live I. multifiliis theronts, control fish were injected with PBS and subgroups were treated with the immuno-suppressant hydrocortisone before fish were challenged with live theronts. Significant up-regulations of genes encoding IgM, IgT, C3, SAA, IL-8, IL-22 and IFN-γ were induced by immunization and challenge. Hydrocortisone treatment had a significant down-regulating effect on genes incoding IgT, IgM, CD4, CD8, IFN-γ, IL-8 and IL-22 in all groups. Immunohistochemistry, using monoclonal antibodies to detect cellular markers, demonstrated active involvement of CD8, MHC II, IgT and IgM positive cells in gill tissue. Putative T-cells (CD8 positive cells) were detected in the intraepithelial lymphoid tissue located at the base of gill filaments and in hyperplastic gill tissue but following infection a clear efflux of these cells was detected. MHC II positive cells were distributed across the gill filaments and accumulated in hyperplastic tissue but hydrocortisone treatment affected their density negatively in both immunized and non-immunized fish. IgT positive cells were present in the epithelial lining of the gill lamellae (suggesting a primary role of this protein in the mucosal defence against the ciliate) whereas IgM positive cells were found only in gill arterioles and the lamellar capillaries. The present work indicates an intensive activity and specialized function of immune cells (B-cells, T-cells and macrophages) and humoral elements such as immunoglobulins IgT and IgM which are orchestrated by cytokines in gill tissue reacting against I. multifiliis.

Systematic identification of protein complexes in Saccharomyces cerevisiae by mass spectrometry.

The recent abundance of genome sequence data has brought an urgent need for systematic proteomics to decipher the encoded protein networks that dictate cellular function. To date, generation of large-scale protein-protein interaction maps has relied on the yeast two-hybrid system, which detects binary interactions through activation of reporter gene expression. With the advent of ultrasensitive mass spectrometric protein identification methods, it is feasible to identify directly protein complexes on a proteome-wide scale. Here we report, using the budding yeast Saccharomyces cerevisiae as a test case, an example of this approach, which we term high-throughput mass spectrometric protein complex identification (HMS-PCI). Beginning with 10% of predicted yeast proteins as baits, we detected 3,617 associated proteins covering 25% of the yeast proteome. Numerous protein complexes were identified, including many new interactions in various signalling pathways and in the DNA damage response. Comparison of the HMS-PCI data set with interactions reported in the literature revealed an average threefold higher success rate in detection of known complexes compared with large-scale two-hybrid studies. Given the high degree of connectivity observed in this study, even partial HMS-PCI coverage of complex proteomes, including that of humans, should allow comprehensive identification of cellular networks.