Project description:Dogs exhibit high genetic diversity due to extensive breeding, and provide a versatile model for genetics, evolution, and complex traits. While RNA synthesis and transcriptional architecture of promoters and enhancers have been extensively analyzed in human, mouse, and fly, little is known about the mechanisms that coordinate gene and enhancer transcription in dog. Here, we combine precision run-on sequencing (PRO-seq) and strand-specific mRNA-seq (mRNA-seq) to measure nascent transcription, mRNA expression and mRNA stability in golden retriever macrophage (DH82) cells. Tracking transcription at nucleotide-resolution uncovers the precise transcription start nucleotides (TSN) genome-wide, identifies the exact locations of promoters and transcribed enhancers, and quantifies transcription machineries at initiation, promoter proximal pause, gene bodies, and termination windows. Moreover, we trigger an instant transcriptional reprogramming using heat shock, and track at nucleotide-resolution, how dog cells coordinate RNA synthesis and mRNA expression across the genome. Taken together, this study describes the transcriptional landscape at nucleotide-resolution, measures RNA synthesis, mRNA expression and mRNA-stability, and identifies mechanisms of gene and enhancer reprogramming in Canis lupus familiaris.

Project description:Allele frequency analysis reveals that the breed is enhanced for genes controlling traits associated with the poodle-type coat, which are perceived to have an association with hypoallergenicity, with no strong signatures of selection for Labrador retriever (LAB) traits. This study provides a blueprint for understanding how dog breeds are formed, highlighting the limited scope of trait selection in defining seemingly new breeds.

Project description:Copper is an essential trace element, but can become toxic when present in abundance. The severe effects of copper-metabolism imbalance are illustrated by the inherited disorders Wilson disease and Menkes disease. The Labrador retriever dog breed is a novel non-rodent model for copper-storage defects displaying identical phenotypic alterations and carrying mutations in genes known to be involved in copper transport. Besides disease initiation and progression of copper accumulation, the molecular mechanisms and pathways involved in copper accumulation and eventually progression towards copper associated chronic hepatitis still remains unclear. Using liver tissue of Labrador retrievers in different stages of copper-associated hepatitis, expression levels targeted at candidate genes as well as transcriptome microarrays, have shed light on involved molecular pathways. At the initial phase, viz. increased hepatic copper levels, transcriptomic alterations in livers revealed enrichment for cell adhesion, developmental, inflammatory, and cytoskeleton pathways. Upregulation of targeted MT1A and COMMD1 mRNA shows the livers first response to rising intrahepatic copper concentrations. In livers with copper-associated hepatitis mainly an activation of inflammatory pathways is detected. Once the hepatitis is in the chronic stage, transcriptional differences are found in cell adhesion adaptations and cytoskeleton remodelling. In view of the high similarities in hepatopathies between men and dog extrapolation of these dog data into human biomedicine seems feasible.

Project description:We develop a method Re-Cappable-seq for determining eukaryotic transcription start sites derived from all RNA polymerases at nucleotide resolution. In particular, this method identifies the Pol-I and Pol-III TSSs, which are missing by CAGE. Applied to human A549 cell line, our method results in the identification of 33,468 and 5,269 high confidence Pol-II and non-Pol-II TSS respectively. Re-Cappable-seq identifies Pol-II TSS with higher specificity than CAGE.

Project description:Stress-induced readthrough transcription results in the synthesis of thousands of downstream-of-gene (DoG) containing transcripts. The mechanisms underlying DoG formation during cellular stress remain unknown. Nascent transcription profiles during DoG induction in human cell lines using TT-TimeLapse-seq revealed that hyperosmotic stress induces widespread transcriptional repression. Yet, DoGs are produced regardless of the transcriptional level of their upstream genes. ChIP-seq confirmed that the stress-induced redistribution of RNA Polymerase (Pol) II correlates with the transcriptional output of genes. Stress-induced alterations in the Pol II interactome are observed by mass spectrometry. While subunits of the cleavage and polyadenylation machinery remained Pol II-associated, Integrator complex subunits dissociated from Pol II under stress conditions. Depleting the catalytic subunit of the Integrator complex, Int11, using siRNAs induces hundreds of readthrough transcripts, whose parental genes partially overlap those of stress-induced DoGs. Our results provide insights into the mechanisms underlying DoG production and how Integrator activity influences DoG transcription. This SuperSeries is composed of the SubSeries listed below.

Project description:In all eukaryotes DNA replication is coupled to histone synthesis to coordinate chromatin packaging of the genome. Canonical histone genes coalesce in the nucleus into the Histone Locus Body (HLB), where gene transcription and 3’ mRNA processing occurs. Both histone gene transcription and mRNA stability are reduced when DNA replication is inhibited, implying that the Histone Locus Body senses the rate of DNA synthesis. In Drosophila melanogaster, the S-phase-induced histone genes are repeated in an ~100 copy repeat unit array, whereas in humans, these histone genes are scattered. In both organisms these genes coalesce into Histone Locus Bodies.

Project description:RESA identifies mRNA regulatory sequences with high resolution

Project description:Nucleotide resolution of RNA polymerase II transcription in human cytomegalovirus

Project description:The conserved human LIN28 RNA-binding proteins function in development, maintenance of pluripotency and oncogenesis. We used PAR-CLIP and a newly developed variant of this method, iDo-PAR-CLIP, to identify LIN28B targets as well as sites bound by the individual RNA binding domains of LIN28B in the human transcriptome at nucleotide resolution. The position of target binding sites reflected the known structural relative orientation of individual LIN28B binding domains, validating iDo-PAR-CLIP. Our data suggest that LIN28B directly interacts with most expressed mRNAs and members of the let-7 microRNA family. The Lin28 binding motif detected in pre-let-7 was enriched in mRNA sequences bound by LIN28B. Upon LIN28B knock down, cell proliferation and the cell cycle were strongly impaired. Quantitative shotgun proteomics of LIN28B depleted cells revealed significant reduction of protein synthesis from its RNA targets that function in translation, mRNA splicing and cell cycle control. Computational analyses provided evidence that the strength of protein synthesis reduction correlated with the location of LIN28B binding sites within target transcripts. We used PAR-CLIP and a newly developed variant of this method, iDo-PAR-CLIP, to identify LIN28B targets as well as sites bound by the individual RNA binding domains of LIN28B in the human transcriptome at nucleotide resolution.

Project description:This experiment identifies hnRNP A1 binding sites transcriptome-wide in Hela cells. HeLa cells with inducible expression of T7-tagged hnRNP A1 were grown to approximately 90% confluence and then subject to iCLIP analysis (following the protocol from Huppertz et al. 2014 (iCLIP: protein-RNA interactions at nucleotide resolution)). The iCLIP library was sequenced using Illumina's HighSeq 1500