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:Regulation of mRNA degradation is critical for a diverse array of cellular processes and developmental cell fate decisions. Although many methods for determining mRNA half-lives rely on transcriptional inhibition or metabolic labelling, these manipulations can influence half-lives or introduce errors in the measurements. Here we use a non-invasive method for estimating mRNA half-lives globally in the early Drosophila embryo using a total RNA-seq time series and Gaussian process regression to model the dynamics of premature and mature mRNAs.

Project description:mRNA abundances are regulated by the opposing forces of transcription and decay, and yet how decay contributes to mRNA abundance regulation is largely unexplored. We addressed this question using genome-wide data on mRNA rates of abundance change, half-lives, and transcription rates of leaf cells responding to a transdifferentiation stimulusulus. Half-life regulation was common (22% of mRNAs underwent changes in half-life), but RNA abundance regulation by decay alone or by decay that supported transcriptional regulation was rare. Instead, most altered RNA half-lives opposed changes in transcription. Oppositionally regulated mRNAs were characterized by large changes in transcription and decay rates yet changes in mRNA abundances were either modest or undetectable, suggestive of RNA buffering. Oppositionally-regulated and buffered RNAs showed very similar dynamics, suggesting use of a common mechanism. The strongest contributions of RNA decay to RNA abundance regulation was in synergistically regulated transcripts, where rate changes in decay and transcription rates worked together to change RNA abundances.

Project description:mRNA abundances are regulated by the opposing forces of transcription and decay, and yet how decay contributes to mRNA abundance regulation is largely unexplored. We addressed this question using genome-wide data on mRNA rates of abundance change, half-lives, and transcription rates of leaf cells responding to a transdifferentiation stimulusulus. Half-life regulation was common (22% of mRNAs underwent changes in half-life), but RNA abundance regulation by decay alone or by decay that supported transcriptional regulation was rare. Instead, most altered RNA half-lives opposed changes in transcription. Oppositionally regulated mRNAs were characterized by large changes in transcription and decay rates yet changes in mRNA abundances were either modest or undetectable, suggestive of RNA buffering. Oppositionally-regulated and buffered RNAs showed very similar dynamics, suggesting use of a common mechanism. The strongest contributions of RNA decay to RNA abundance regulation was in synergistically regulated transcripts, where rate changes in decay and transcription rates worked together to change RNA abundances.

Project description:RHAU (RNA helicase-associated with AU-rich element) is a DExH protein that was originally identified as a factor accelerating AU-rich element-mediated mRNA degradation. The finding that RHAU is predominantly localized in the nucleus, despite that mRNA degradation occurs in cytoplasm, prompted us to consider nuclear functions of RHAU. In HeLa cells, RHAU was localized throughout the nucleoplasm with some concentration in nuclear speckles in a manner dependent on ATPase activity. Transcriptional arrest altered its localization to nucleolar caps where it was colocalized with other RNA helicases, p68 and p72, suggesting that RHAU is involved in transcription-related RNA metabolism in the nucleus. To see whether RHAU affects global gene expression either transcriptionally or posttranscriptionally, we performed microarray analysis using total RNA prepared from RHAU-depleted HeLa cell lines, measuring both steady-state mRNA levels and mRNA half-lives by ActinomycinD-chase. We found that most transcripts whose steady-state levels were affected by RHAU knockdown did not show changes in their half-lives, suggesting the involvement of transcriptional regulation for these transcripts. We propose that RHAU has dual functions involved in synthesis and degradation of mRNA in different subcellular compartments. Keywords: mRNA decay study using HeLa cells expressing shRNA

Project description:In this work, we determine total mRNA decay rates in rpb1-1 and rpb1-1/caf1∆ cells, calculate half-lives in rpb1-1/caf1∆ cells relative to rpb1-1 cells and correlate them with codon optimality.

Project description:The eukaryotic mRNA life cycle includes transcription, nuclear mRNA export and degradation. To quantify all these processes simultaneously, we perform thiol-linked alkylation after metabolic labeling of RNA with 4-thiouridine (4sU), followed by sequencing of RNA (SLAM-seq) in the nuclear and cytosolic compartments. We develop a model that reliably quantifies mRNA synthesis, nuclear export, and nuclear and cytosolic degradation rates on a genome-wide scale. We find that nuclear degradation of polyadenylated mRNA is negligible and nuclear mRNA export is slow, while cytosolic mRNA degradation is comparatively fast. Consequently, an mRNA molecule generally spends most of its life in the nucleus. We also observe large differences in the nuclear export rates of different 3’UTR transcript isoforms. Furthermore, we identify genes whose expression is abruptly induced upon metabolic labeling. These transcripts are exported substantially faster than average mRNAs, suggesting the existence of alternative export pathways. Our results highlight nuclear mRNA export as a limiting factor in mRNA metabolism and gene regulation.

Project description:Proteins exhibit dynamics in their expression level in response to intracellular and extracellular signals. Regulation of protein turnover allows cells to rapidly and efficiently remodel their proteomes. It is known that proteins can show very different turnover rates in different tissue of the same organism, but little is known about protein turnover rates in different brain cell types. We used a dynamic SILAC approach to determine protein half-lives in primary hippocampal cultures (containing a mixture of neurons and glia cells) as well as in neuron-enriched and glia-enriched cultures. We determined the protein half-lives for over 5100 proteins and found half-lives ranging from <1 to > 20 days with a median half-life of 5.4 days in mixed cultures. Membrane proteins as a group were shorter-lived and mitochondrial proteins, surprisingly, were longer-lived. Proteins in glia possessed significantly shorter half-lives than the same proteins in neurons. The presence of glia sped up or slowed down the half-lives of neuronal proteins. Our results demonstrate that both the cell-type of origin as well as the nature of the extracellular environment have potent influences on protein turnover.

Project description:The CCR4-NOT deadenylase complex has a critical function to trigger mRNA decay and various biological events. To understand roles of the complex in adipocyte function, we compare mRNA half-lives between control and Cnot complex-deficient mature adipocytes from iWAT and BAT.

Project description:Gene expression analysis requires accurate measurements of global RNA degradation rates, earlier problematic with methods disruptive to cell physiology. Recently, metabolic RNA labeling emerged as an efficient and minimally invasive technique applied in mammalian cells. Here, we have adapted SH-Linked Alkylation for the Metabolic Sequencing of RNA (SLAM-Seq) for a global mRNA stability study in yeast using 4-thiouracil pulse-chase labeling. We assign high-confidence half-life estimates for 67.5 % of expressed ORFs, and measure a median half-life of 9.4 min. For mRNAs where half-life estimates exist in the literature, their ranking order was in good agreement with previous data, indicating that SLAM-Seq efficiently classifies stable and unstable transcripts. We then leveraged our yeast protocol to identify targets of the Nonsense-mediated decay (NMD) pathway by measuring the change in RNA half-lives; instead of steady-state RNA level changes. With SLAM-Seq, we assign 580 transcripts as putative NMD targets, based on their measured half-lives in wild-type and upf3Δ mutants. We find 225 novel targets, and observe a strong agreement with previous reports of NMD targets, 61.2 % of our candidates being identified in previous studies.This indicates that SLAM-Seq is a simpler and more economic method for global quantification of mRNA half-lives. Our adaptation for yeast yielded global quantitative measures of the NMD effect on transcript half-lives, high correlation with RNA half-lives measured previously with more technically challenging protocols, and identification of novel NMD regulated transcripts that escaped prior detection.