Project description:We characterize a Cre-activated TRAP allele (Rosa26fsTRAP) to show that endothelium-specific activation of Rosa26fsTRAP identifies endothelial cell enriched transcripts, and that cardiomyocyte-restricted TRAP is a useful means to identify genes that are differentially expressed in cardiomyocytes in a disease model. We also show that TRAP is an effective means to study translational regulation, and we several nuclear-encoded mitochondrial genes are under strong translational control. These RNA-seq data show that the TRAP strategy and the Rosa26fsTRAP allele will be useful tools to probe cell type specific transcriptomes, and to study translational regulation. Study TRAP RNA and total RNA in two cases: heart specific tissues, Banding or Sham, using RNA-seq technology.

Project description:We characterize a Cre-activated TRAP allele (Rosa26fsTRAP) to show that endothelium-specific activation of Rosa26fsTRAP identifies endothelial cell enriched transcripts, and that cardiomyocyte-restricted TRAP is a useful means to identify genes that are differentially expressed in cardiomyocytes in a disease model. We also show that TRAP is an effective means to study translational regulation, and we several nuclear-encoded mitochondrial genes are under strong translational control. These RNA-seq data show that the TRAP strategy and the Rosa26fsTRAP allele will be useful tools to probe cell type specific transcriptomes, and to study translational regulation.

Project description:Translating ribosome affinity purification (TRAP) methods allow cell-specific recovery of polyribosome-associated RNAs by genetic tagging of ribosomes in selected cell populations. In this study, we purified and analysed the polyribosome-associated RNA fraction of zebrafish embryo´s retinas at 22 hours post-fertilization. To this aim, we generated a transgenic strain in which the tagged ribosomes expression is restricted to the retina cells due to the activity of a specific promoter.

Project description:Post-transcriptional regulation including mRNA binding to ribosomes plays an important role in determining cell-type-specific gene expression patterns. Here, we applied an approach that profiles cell-type-specific mRNAs. The Translating Ribosome Affinity Purification method (TRAP; Heiman et al., Cell, 2008 and Doyle et al., Cell, 2008) was developed in mice and has been combined with the UAS/Gal4 system in Drosophila (Thomas et al., PLoS ONE, 2012). TRAP is a powerful method to find cell-type-specific differences at the level of the 'translatome' (Dougherty, Schmidt, Nakajima, & Heintz, Nucleic Acids Research, 2010). In parallel to published efforts, we developed and implemented the method for the fly and compared distinct head cell types and identified cell-type-specific transcript classes with neuronal (e.g. receptor-, neuropeptide- or hormone activity) or glial function (e.g. transporter activity). Neuronal TRAP genes are over-represented in the brain, larval CNS and thoracico-abdominal ganglion (Chintapalli, Wang, & Dow, Nature Genetics, 2007). Using cell-type-to-cell-type comparisons (e.g. neurons vs. glia), instead of a given cell population to the total (e.g. neurons vs. head), the differences could be identified with greater resolution. TRAP uncovered more neuronal genes compared to neuronal RNA polymerase II ChIP-seq data (Schauer et al., Cell Reports, 2013). Thus, TRAP data confirm the importance of post-transcriptional regulation in defining cell identity. TRAP is one of the best methods to reveal differential "omics" data among distinct cell types by profiling ribosome-bound mRNAs. TRAP is a promising tool to reveal cell-type-specific transcriptional and translational changes in a perturbed environment.

Project description:The long term goal is to define the transcriptional changes that accompany pericyte-to-myofibroblast transition in fibrotic kidney disease. Medullary pericytes are identified by their expression of a eGFPL10a fusion protein whose expression is driven by a Col1a1 promoter. Pericyte-specific RNA is generated by eGFP-affinity purification of polysomes from medullary lysates and then subject to microarray analysis. Col1a1-eGFPL10a mice were subject to Sham or unilateral ureteral obstruction surgery. Sham kidneys were collected at day 0, and UUO kidneys were collected at day 2 or day 5 for TRAP.

Project description:The long term goal is to define the transcriptional changes that accompany pericyte-to-myofibroblast transition in fibrotic kidney disease. Medullary pericytes are identified by their expression of a eGFPL10a fusion protein whose expression is driven by a Col1a1 promoter. Pericyte-specific RNA is generated by eGFP-affinity purification of polysomes from medullary lysates and then subject to microarray analysis.

Project description: Not available

Project description: Not available

Project description:Translational profiling of zebrafish retina cells using translating ribosome affinity purification methods

Project description:Col-0 transgenic plants expressing MSH1P::FLAG::RPL18 were generated in both msh1 homozygous mutant (SAIL-877-F01) and wild type backgrounds with cloned MSH1 sequence described in Xu et al. (2011) and with transformation by the floral dip method (Clough and Bent, 1998). Positive transgenic lines were screened for FLAG tag by immunoblotting methods. Polysomal mRNA from MSH1-specific cells was obtained by ribosome purification using the TRAP method essentially as reported by (Reynoso et al., 2015) from floral stem tissues.