Project description:gabrg2-KO whole zebrafish larval brain differential expression analysis

Project description:We conducted a whole genome transcriptome analysis to examine significant gene expression changes in whole zebrafish larvae at 4 dpf between nlrc3l st73 mutants compared with their control siblings.

Project description:Single-cell RNA-sequencing (scRNA-seq) was applied to identify and characterise macrophage subsets that responded to larval zebrafish muscle injury. The Tg(mpeg1:mCherry) transgenic zebrafish line was utilised to isolate mCherry-expressing macrophages by FACS. Following needle-stab muscle injury of a 4 days post fertilisation (dpf) larvae, the wound site was dissected out at 1, 2, and 3 days post injury (dpi) for macrophage isolation. Macrophages isolated from 4 dpf-uninjured larvae were also included. This analysis led to the identification of 8 discrete clusters of macrophages, one of which corresponded to uninjured macrophages. The 7 wound-present macrophage subsets highlighted greater macrophage heterogeneity than previously described in an in vivo skeletal muscle injury context.

Project description:Label-free mass spectrometry-based quantitative proteomics was applied to a larval zebrafish spinal cord injury model, which allows axon regeneration and functional recovery within two days (days post lesion; dpl) after a spinal cord transection in 3 day-old larvae (dpf). Proteomic profiling of the lesion site was performed at 1 dpl and 2 dpl as well as corresponding age-matched unlesioned control tissue (4 dpf as control for 1 dpl; 5 dpf as control for 2 dpl).

Project description:Blue mussel larvae were fed, in a first group, a balanced diet of essential fatty acids (EFAs) provided by a cocktail diet (COC) from three algal species. Larvae were cultured in three separate tanks from hatching, 0 day post-fertilization (DPF) until 42 DPF. Treated larvae were fed a deficient diet (Tiso) that contains low levels of arachidonic acid (AA) and eicosapentaenoic acid (EPA), two EFAs necessary for larval development, performance, and survival. The goal is to identify coordinated patterns of gene expression and understand their predictive function in relation to growth and mortality during early developmental stages of the blue mussel Mytilus edulis. In order to understand the mechanisms by which growth and survival drive an organism to the full range of its adaptation, we de novo assembled of the mussel transcriptome during early development using next-generation sequencing (NGS) technology, then designed customized microarrays targeting every developmental stage, which encompass major transitions in tissue organization of the fast-evolved blue mussel

Project description:In this work we investigated how the brain proteome of the larval zebrafish is modified by behavioral adaptation to the environmental challenge of a water vortex. We monitored the behavior of larvae and observed that they behaviorally adapted to the presence of a water vortex. We obtained the larval zebrafish brain proteome by extracting brains from zebrafish larvae and analyzing them using and LFQ-based LC-MS/MS-approach. In total we identified 5929 proteins in the larval brain. Within this proteome, we identified 57 proteins that were significantly regulated following experience of the water vortex: 41 proteins were up regulated and 16 were down regulated. Of these, 29 proteins are known to have neuronal functions, 17 proteins are known to have other cellular functions, and 11 proteins are still uncharacterized.

Project description:Label-free mass spectrometry-based quantitative proteomics was applied to a larval zebrafish spinal cord injury model, which allows axon regeneration and functional recovery within two days (days post lesion; dpl) after a spinal cord transection in 3 day-old larvae (dpf). Proteomic profiling was performed of the lesion site at 1 dpl in control animals and animals with pdgfrb+ cell-specific overexpression of either zebrafish chondoradherin (chad; chad-mCherry fusion), fibromodulin a (fmoda; fmoda-mCherry fusion), lumican (lum; lum-mCherry fusion) or prolargin (prelp; prelp-mCherry fusion).

Project description:Blue mussel larvae were fed, in a first group, a balanced diet of essential fatty acids (EFAs) provided by a cocktail diet (COC) from three algal species. Larvae were cultured in three separate tanks from hatching, 0 day post-fertilization (DPF) until 42 DPF. Treated larvae were fed a deficient diet (Tiso) that contains low levels of arachidonic acid (AA) and eicosapentaenoic acid (EPA), two EFAs necessary for larval development, performance, and survival. The goal is to identify coordinated patterns of gene expression and understand their predictive function in relation to growth and mortality during early developmental stages of the blue mussel Mytilus edulis. In order to understand the mechanisms by which growth and survival drive an organism to the full range of its adaptation, we de novo assembled of the mussel transcriptome during early development using next-generation sequencing (NGS) technology, then designed customized microarrays targeting every developmental stage, which encompass major transitions in tissue organization of the fast-evolved blue mussel Two experimental conditions, COC and Tiso diets. Biological replicates 3 culture replicate per stage of development for 5 stages of development. Eggs and trocophore larvae did not undertake treatments

Project description:Genome-wide microarray analysis of the effects of swim-training on zebrafish larval development. Zebrafish were subjected to swim-training from 5 days post fertilization (dpf) until 10 dpf. Subsequently, we performed a genome-wide microarray analysis of trained and control fish at 10 dpf. The goal of the project was to investigate the effects of swim-training on the gene expression level during zebrafish larval development

Project description:In this study, we performed RNA-seq on 5 dpf whole larvae of uhrf1-hi272 mutants and phenotypically wild-type siblings to determine changes in the transcriptomic profile.