Project description:Transient transcriptome sequencing and kinetic modeling suggest how the kinetics and yield of RNA splicing are encoded in the human genome.

Project description:In this work, we quantified mRNA flow rates between subcellular compartments in mouse embryonic stem cells. Combining metabolic RNA labeling, biochemical cell fractionation and RNA sequencing with mathematical modeling we were able to determine the kinetic rates of nuclear pre-, nuclear mature, cytosolic and membrane mRNA derived from more than 9000 protein-coding genes. For more than 5000 genes, we additionally estimated the transcript elongation rate. For most of the transcripts, mature nuclear half-lives are the longest, suggesting nuclear retention to be the rate-limiting step in the mRNA life cycle. Genes encoding transcription factors and immediate early genes possess fast kinetic rates, specifically a short nuclear half-life. Differentially localized mRNAs exhibit distinct combinations of rate constants, suggesting modular control within subcellular compartments. We show that membrane stability is high for membrane-localized mRNA and that cytosolic stability is high for cytosol-localized mRNA. Genes encoding target signals, such as signal peptides or transmembrane domains, have low cytosolic and high membrane half-lives with only slight differences between target signals. Nuclear-encoded mitochondrial proteins show long nuclear mature half-lives and otherwise similar features of cytoplasmic kinetics that do not resemble co-translational targeting to the mitochondria.

Project description:In this work, we quantified mRNA flow rates between subcellular compartments in mouse embryonic stem cells. Combining metabolic RNA labeling, biochemical cell fractionation and RNA sequencing with mathematical modeling we were able to determine the kinetic rates of nuclear pre-, nuclear mature, cytosolic and membrane mRNA derived from more than 9000 protein-coding genes. For more than 5000 genes, we additionally estimated the transcript elongation rate. For most of the transcripts, mature nuclear half-lives are the longest, suggesting nuclear retention to be the rate-limiting step in the mRNA life cycle. Genes encoding transcription factors and immediate early genes possess fast kinetic rates, specifically a short nuclear half-life. Differentially localized mRNAs exhibit distinct combinations of rate constants, suggesting modular control within subcellular compartments. We show that membrane stability is high for membrane-localized mRNA and that cytosolic stability is high for cytosol-localized mRNA. Genes encoding target signals, such as signal peptides or transmembrane domains, have low cytosolic and high membrane half-lives with only slight differences between target signals. Nuclear-encoded mitochondrial proteins show long nuclear mature half-lives and otherwise similar features of cytoplasmic kinetics that do not resemble co-translational targeting to the mitochondria.

Project description:DNA microarray technology is a powerful tool for getting the overview of gene expression in biological samples. Although the successful application of microarray-based expression analysis was demonstrated in a number of applications, the main problem with this approach is the fact that expression levels deduced from hybridization experiments do not necessarily correlate with RNA concentrations. Moreover, oligonucleotide probes corresponding to the same gene can give different hybridization signals. Apart from cross-hybridizations and differential splicing, this could be due to secondary structures of probes or targets. In addition, for low copy genes, hybridization equilibrium may be reached after hybridization times much longer than the one commonly used (overnight, 15 hours). Thus, hybridization signals could depend on kinetic properties of the probe, which may vary between different oligonucleotide probes immobilized on the same microarray. To validate these hypothesis, on-chip hybridization kinetics and duplexes thermostability analysis were performed using oligonucleotide microarrays containing 50-mer probes corresponding to mouse genes. We demonstrate that differences in hybridization kinetics between the probes can influence the interpretation of expression data. Ways to improve the reliability of microarray-based expression analysis are discussed. Keywords: kinetics, gene expression, microarrays Total RNA were extracted from 5 thymus and 6 cortex of B10D2 mice. For each tissue, equal amounts of each RNA were pooled and 15M-BM-5g were labeled by reverse-transcription and hybridized on neurotransmission microarrays. Three replicates of each experiment have been performed.

Project description:Despite the critical regulatory function of promoter-proximal pausing, the influence of pausing kinetics on transcriptional control remains an active area of investigation. Here, we present Start-TimeLapse-seq (STL-seq), a method that captures the genome-wide kinetics of short, capped RNA turnover and reveals principles of regulation at the pause site. By measuring the rates of release into elongation and premature termination through inhibition of pause release, we determine that pause-release rates are highly variable and most promoter-proximal paused RNA Polymerase II molecules prematurely terminate (~80%). The preferred regulatory mechanism upon a hormonal stimulus (20-hydroxyecdysone) is to influence pause-release rather than termination rates. Transcriptional shutdown occurs concurrently with induction of promoter-proximal termination under hyperosmotic stress but paused transcripts from TATA box-containing promoters remain stable, demonstrating an important role for cis-acting DNA elements in pausing. STL-seq dissects the kinetics of pause release and termination, providing an opportunity to identify mechanisms of transcriptional regulation.

Project description:DNA microarray technology is a powerful tool for getting the overview of gene expression in biological samples. Although the successful application of microarray-based expression analysis was demonstrated in a number of applications, the main problem with this approach is the fact that expression levels deduced from hybridization experiments do not necessarily correlate with RNA concentrations. Moreover, oligonucleotide probes corresponding to the same gene can give different hybridization signals. Apart from cross-hybridizations and differential splicing, this could be due to secondary structures of probes or targets. In addition, for low copy genes, hybridization equilibrium may be reached after hybridization times much longer than the one commonly used (overnight, 15 hours). Thus, hybridization signals could depend on kinetic properties of the probe, which may vary between different oligonucleotide probes immobilized on the same microarray. To validate these hypothesis, on-chip hybridization kinetics and duplexes thermostability analysis were performed using oligonucleotide microarrays containing 50-mer probes corresponding to mouse genes. We demonstrate that differences in hybridization kinetics between the probes can influence the interpretation of expression data. Ways to improve the reliability of microarray-based expression analysis are discussed. Keywords: kinetics, gene expression, microarrays

Project description:Kinetics-seq enables comprehensive profiling of single-cell RNA kinetics in vivo to reveal dynamic tumor heterogeneity

Project description:The RNA-guided DNA endonuclease Cas9 is a powerful tool for genome editing. Little is known about the kinetics and fidelity of the double-strand break (DSB) repair process that follows a Cas9 cutting event in living cells. Here, we developed a strategy to measure the kinetics of DSB repair for single loci in human cells. Quantitative modeling of repaired DNA in time series after Cas9 activation reveals variable and often slow repair rates, with half-life times up to ~10 h. Furthermore, repair of the DSBs tends to be error-prone. Both classical and microhomology-mediated end-joining pathways contribute to the erroneous repair. Estimation of their individual rate constants indicates that the balance between these two pathways changes over time and can be altered by additional ionizing radiation. Our approach provides quantitative insights into DSB repair kinetics and fidelity in single loci, and indicates that Cas9-induced DSBs are repaired in an unusual manner.

Project description:Kinetics of transcriptome during hepatic conversion [RNA-seq]

Project description:The binding and dissociation of RNA Binding Proteins (RBPs) to their cognate sites on cellular RNAs are critical for the regulation of gene expression. Yet, association and dissociation kinetics of RBPs at individual cellular binding sites have not been experimentally accessible. Inaccessibility of binding and dissociation kinetics of RBPs in cells severely limits or even precludes the establishment of quantitative connections between RBP-RNA interactions and cellular RBP function. Here, we describe an approach to measure binding and dissociation kinetics of the RBP Dazl at thousands of individual binding sites in cells. We then show how these kinetic parameters inform a quantitative understanding of the cellular function of Dazl.