Project description:Transcriptomics of Laminaria japonica

Project description:Gametophytes sequencing for Saccharina japonica

Project description:Transcriptomic analysis of Laminaria japonica

Project description:Transcriptome data of Laminaria japonica under amantadine stress

Project description:The effect of Laminaria japonica on gut health in piglets

Project description:Laminaria setchellii

Project description:Laminaria sinclairii

Project description:Laminaria ephemera

Project description:The proteome of the gametophytes of Diplazium maximum, a temperate Himalayan Polypoidale fern was studied in response to micro-environmental changes. The study was expected to reveal the key proteins associated with a gametophyte’s response to sucrose mediated changes in osmotic potential. A major aim of the study was to identify proteins that would express differentially under micro-environmental stress and also to gain an understanding of the adaptive responses/competence of D. maximum gametophytes. The genes/proteins identified in the study have potential utility in various crop improvement programs.

Project description:Seaweeds may represent immunostimulants that could be used as health-promoting fish feed components thereby offering an alternative for the use of antibiotics. This study was performed to gain insights into the immunomodulatory effects of dietary seaweeds in Atlantic salmon. Specifically tested were 10% inclusion levels of Laminaria digitata (SW1) and a commercial blend of seaweeds (Oceanfeed®) (SW2) against a fishmeal based control diet (FMC). Differences between groups were assessed in growth, feed conversion ratio (FCR) and blood parameters hematocrit (Hct) and hemoglobin (Hb). After a LPS challenge of fish representing each of the three groups, RNAseq was performed on head kidneys to determine transcriptomic differences in response to the immune activation, to our knowledge for the first time in fish in this context. Atlantic salmon fed with dietary seaweeds showed slightly higher FCRs and more homogenous growth but in general no major differences in performance in comparison with fishmeal fed fish. RNAseq resulted in ~154 million reads which were mapped against a NCBI Salmo salar reference and against a de novo assembled Salmo salar reference for analyses of expression of immune genes and ontology of immune processes among the 87,600 cDNA contigs. The dietary seaweeds provoked a more efficient immune response which involved more efficient identification of the infection site, and processing and presentation of antigens. More specifically, chemotaxis and the chemokine-mediated signaling pathway with involvement of genes such as C-C motif chemokine 19 were improved and the defense response to Gram-positive bacterium reduced. The predicted integrin alpha-2-like gene had by far the highest up-regulated expression and may therefore represent a key marker gene of the LPS immune response in salmonids. Specific Laminaria digita effects included reduction of the cytokine-mediated signalling pathway as indicated by the cytokine macrophage migration inhibitory factor, and interferon-gamma-mediated signalling as indicated by STAT1 and the gamma-interferon-inducible lysosomal thiol reductase precursor. Highly upregulated and specific for this diet was the expression of Major histocompatibility complex class I-related gene protein. The commercial blend of seaweeds caused more differential expression than Laminaria digita and improved immune processes such as receptor-mediated endocytosis, inflammatory response, cell adhesion and response to lipopolysaccharide. Particularly expression of many important immune receptors was up-regulated illustrating increased responsiveness. NF-kappa-B inhibitor alpha is an important gene that marked the difference between both seaweed diets as Laminaria digita inhibits the production of this cytokine while the blend of seaweeds stimulates it. It can be concluded that replacing fishmeal partly with seaweeds such as Laminaria digita can have important modulatory effects on the immune capacity of Atlantic salmon resulting in a more efficient immune response.