Project description:Regulation of RNA levels is critical for the response to external stimuli and determined through the interplay between RNA production, processing and degradation. Despite the centrality of these processes, most global studies of RNA regulation do not distinguish their separate contributions and relatively little is known about how they are temporally integrated. Here, we combine metabolic labeling of RNA with advanced RNA quantification assays and computational modeling to estimate RNA transcription and degradation during the response of immune dendritic cells (DCs) to pathogens, a critical and tightly regulated step in innate immunity. We find that transcription regulation plays a major role in shaping most temporal changes in RNA levels, but that changes in degradation rate are important for shaping sharp M-bM-^@M-^XpeakedM-bM-^@M-^Y responses. We find that transcription changes precede corresponding RNA changes by a small lag (15-30 min), which is shorter for induced than for repressed genes. Massively parallel sequencing of the entire RNA population M-bM-^@M-^S including non-polyadenylated transcripts M-bM-^@M-^S allows us to estimate RNA processing, and identify specific groups of transcripts, mostly cytokines and transcription factors, undergoing enhanced mRNA maturation. This suggests an additional role for splicing in regulating mRNA maturation. Our method provides a new quantitative approach to study key steps in the integrative process of RNA regulation. Sequencing of 4sU-labeled RNA taken from a 7 samples time-series (one sample every 1 hour) during the response of DCs to LPS stimulation. 4-thiouridine was added 45 minutes prior to sample collection. Data presented here for six timepoints: 0, 1, 3-6 hrs. 2hr timepoint not included.

Project description:The study was to identify candidate S-acylated proteins from LNCaP cells by coupling SILAC quantification with ABE enrichment of S-acylated proteins and GeLC-MS/MS analysis. Another goal is to determine the ratio of candidate S-acylated proteins versus of co-isolated non-S-acylated proteins.

Project description:This SuperSeries is composed of the SubSeries listed below. Refer to individual Series

Project description:The c-myc proto-oncogene product, Myc, is a transcription factor that binds thousands of genomic loci. Recent work suggested that rather than up- and down-regulating selected groups of genes, Myc targets all active promoters and enhancers in the genome (a phenomenon termed "invasion") and acts as a general amplifier of transcription. However, the available data did not readily discriminate between direct and indirect effects of Myc on RNA biogenesis. We addressed this issue with genome-wide chromatin immunoprecipitation and RNA expression profiles during B-cell lymphomagenesis in mice, in cultured B-cells and fibroblasts. Consistent with long-standing observations, we detected general increases in total RNA or mRNA copies per cell (hereby termed "amplification") when comparing actively proliferating cells with control quiescent cells: this was true whether cells were stimulated by mitogens (requiring endogenous Myc for a proliferative response) or by deregulated, oncogenic Myc activity. RNA amplification and promoter/enhancer invasion by Myc were separable phenomena that could occur without one another. Moreover, whether or not associated with RNA amplification, Myc drove the differential expression of distinct subsets of target genes. Hence, while having the potential to interact with all active/poised regulatory elements in the genome, Myc does not directly act as a global transcriptional amplifier. Instead, our results imply that Myc activates and represses transcription of discrete gene sets, leading to changes in cellular state that can in turn feed back on global RNA production and turnover. Total RNA profiling of gene expression upon Myc regulation in two different cell types by Illumina sequencing

Project description:Joint profiling of chromatin accessibility and gene expression from the same single cell provides critical information about cell types in a tissue and cell states during a dynamic process. These emerging multi-omics techniques help the investigation of cell-type resolved gene regulatory mechanisms. Here, we developed in situ SHERRY after ATAC-seq (ISSAAC-seq), a highly sensitive and flexible single cell multi-omics method to interrogate chromatin accessibility and gene expression from the same single cell. We demonstrated that ISSAAC-seq is sensitive and provides high quality data with orders of magnitude more features than existing methods. Using the joint profiles from thousands of nuclei from the mouse cerebral cortex, we uncovered major and rare cell types together with their cell-type specific regulatory elements and expression profiles. Finally, we revealed distinct dynamics and relationships of transcription and chromatin accessibility during an oligodendrocyte maturation trajectory.

Project description:Elevated palmitic acid, a most abundant saturated fatty acid, is a risk factor for obesity complications. Here, we report that palmitic acid impairs spermatogenesis by inducing abnormal palmitoylation in Sertoli cells. Firstly, we proposed a correlation between palmitic acid and spermatogenesis by reporting a significant elevation of serum palmitic acid levels in patients with dyszoospermia. In palmitic acid -treated mice, the blood-testis barrier was found to be disrupted, and decreased tight junction protein expression was observed in palmitic acid-treated Sertoli cells. Palmitic acid entered the endoplasmic reticulum and induced endoplasmic reticulum stress, resulting in damage to Sertoli cell barriers.

Project description:Pulse-chase experiment using SLAM-seq in WT, PHF3KO, and dSPOC, HEK293 cells

Project description:mTRAN proteins are components of the plant mitochondrial small subunits, thought to bind the mRNA 5' regions to initiate translation. This experiment was designed to identify the mTRAN1 binding regions on the plant mitochondrial mRNAs

Project description:To study the gene profiling of different cardiac adipogenic progenitor populations, we isolated individual cells from postnatal 3-week heart and performed single-cell RNA-sequencing. Single cell suspensions from isolated mouse heart were prepared by retrograde Langendorff perfusion. Briefly, mouse at P3W was administered with 0.2 mL heparin sodium salt solution (1000 IU/mL) via intraperitoneal injection and then euthanized by CO2 asphyxiation. The heart was harvested and hung onto the Langendorff apparatus, followed by perfusing with modified Tyrode’s solution (MTS) for 2 min. The heart was next perfused with MTS containing 0.4 mg/ mL collagenase II and 25 µg/ mL DNase I for 10 min. After removed from cannula, atria and valves were removed and ventricles were minced with fine forceps. Cells were filtered through a 70 µm cell strainer and centrifuged at 30x g for 5 minutes at 4°C to remove most cardiomyocytes. The cell suspension was carefully transferred into a new 15 mL centrifuge tube and centrifuged at 300x g for 5 minutes at 4°C. Cell pellet was washed and suspended in DMEM containing 10% FBS for single-cell sequencing. Single cell library was generated using 10x Genomic Chromium system with the v3 single cell reagent kit. Sequencing of library was performed on Illumina NovoSeq 6000 platform.

Project description:Tergeted SLAM seq of WT, PHF3 KO and dSPOC, HEK293 cells