Project description:RNA decay was measured in Prochlorococcus after inhibition of transcription by rifampicin using customized Affymetrix gene expression arrays. RNA turnover plays an important role in the gene regulation of microorganisms and influences their speed of acclimation to environmental changes. We investigated whole-genome RNA stability of Prochlorococcus, a relatively slow-growing marine cyanobacterium doubling approximately once a day, which is extremely abundant in the oceans. Using a combination of microarrays, quantitative RT-PCR and a new algorithm for determining RNA decay rates, we found a median half-life of 2.4 min and a median decay rate of 2.6 min for expressed genes – two-fold faster than that reported for any organism. The shortest transcript half-life (33 seconds) was for a gene of unknown function, while some of the longest (ca. 18 min) were for highly expressed genes. Genes organized in operons displayed intriguing mRNA decay patterns, such as increased stability, and delayed onset of decay with greater distance from the transcriptional start site. The same phenomenon was observed on a single probe resolution for genes greater than 2 kb. We hypothesize that the fast turnover relative to generation time in Prochlorococcus may enable a swift response to environmental changes through rapid recycling of nucleotides, which could be advantageous in nutrient poor oceans. Our growing understanding of RNA half-lives will inform on the modelling of cell processes and help interpret the growing bank of metatranscriptomic studies of wild populations of Prochlorococcus. The surprisingly complex decay patterns of large transcripts reported here, and the method developed to describe them, will open new avenues for the investigation and understanding of RNA decay for all organisms. Prochlorococcus cells were treated with rifampicin, which prevents initiation of new transcripts. Cells were harvested at 0 min (before rifampicin addition), 2.5 min, 5 min, 10 min, 20 min, 40 min and 60 min after rifampicin addition.

Project description:Prochlorococcus is an obligate marine microorganism which are dominant autotroph in tropical and subtropical central oceans. However, what is the low salinity boundary and how Prochlorococcus would response to low salinity exposure is still unknown. In this study, we first tested the growing salinity range of two Prochlorococcus strains, NATL1A and MED4, and then compared the global transcriptome of their low salinity acclimated cells and cells growing in normal seawater salinity. We found that MED4 could be acclimated in the lowest salinity of 25% and NATL1A could be acclimated in the lowest salinity of 28%. Measurement of the effective quantum yield of PSII photochemistry (Fv/Fm) indicated that both strains were stressed when growing in salinity lower than 34%. The transcriptomic response of NATL1A and MED4 were approximately different, with much more genes having changed transcript abundance in NATL1A than in MED4. To cope with low salinity, NATL1A downregulated the transcript of most genes involved in translation, ribosomal structure and biogenesis, while MED4 upregulated those genes. Moreover, low salinity acclimated NATL1A cells suppressed ATP-producing genes and induced the expression of photosynthesis related genes, while low salinity acclimated MED4 upregulated ATP-producing genes and downregulated photosynthesis related genes. These results indicate that the response to low salinity stress of different Prochlorococcus strains could be distinct. The study provided the first glimpse into the growing salinity range of Prochlorococcus cells and their global gene expression changes due to low salinity stress.

Project description:We calculated half-life values of mRNAs quantified by RNA-Seq by a suitable method of normalization. We determined the half-lives of more than 2200 mRNAs in the Stenotrophomonas maltophilia D457 wild-type strain and in an isogenic RNase G deficient mutant. Median half-lives were 2,74 and 3 min in the wild-type and the rng-deficient mutant respectively. We found an overall enhancement of half-life times of mRNAs when the gene encoding RNase G is lacking, showing that many RNAs are targets of RNase G in S. maltophilia. For achieving such goal, we propose a method for the normalization of RNA-Seq based studies on global bacterial mRNA decay.

Project description:Protein turnover affects protein abundance and phenotypes. Comprehensive investigation of protein turnover dynamics has the potential to provide substantial information about gene expression. Here we report a large-scale protein turnover study in Salmonella Typhimurium during infection by quantitative proteomics. Murine macrophage-like RAW 264.7 cells were infected with SILAC labeled Salmonella. Bacterial cells were extracted after 0, 30, 60, 120 and 240 min. Mass spectrometry analyses yielded information about Salmonella protein turnover dynamics and a software program named Topograph was used for the calculation of protein half lives. The half lives of 311 proteins from intracellular Salmonella were obtained. For bacteria cultured in control medium (DMEM), the half lives for 870 proteins were obtained. The calculated median of protein half lives was 69.13 min and 99.30 min for the infection group and the DMEM group respectively, indicating an elevated protein turnover at the initial stage of infection. Gene ontology analyses revealed that a number of protein functional groups were significantly regulated by infection, including proteins involved in ribosome, periplasmic space, cellular amino acid metabolic process, ion binding and catalytic activity. The half lives of proteins involving in purine metabolism pathway were found to be significantly shortened during infection.

Project description:Prochlorococcus is the most abundant photosynthetic organism on Earth, contributing significantly to the global primary production and playing a prominent role in biogeochemical cycles. Prochlorococcus requires the capability to accommodate to environmental changes in order to proliferate in oligotrophic oceans, in particular regarding nitrogen availability. A precise knowledge of the composition and changes of the proteome is necessary to gain fundamental insights into such response. Here we study the effects of extreme nitrogen limitation, a feature of the oligotrophic oceans inhabited by this organism.

Project description:We measured the the dwell time of existed paused RNAPII at the promoter by mammalian native elongating transcript sequencing (mNET-seq). We found a median RNAPII half-life of 5.3 min at protein-coding genes in DMSO pre-treated control mESCs, whereas the RNAPII half-life at these genes significantly slowdown to 8.96 min when pre-treated with Auxin in the DPY30-mAID degron cell. The data suggested that loss H3K4me3 directly slows down the release of paused RNAPII throughout genes.

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.

Project description:Extracellular vesicles are small (~50–200 nm diameter) membrane-bound structures released by cells from all domains of life. While extremely abundant in the oceans, our understanding of their functions, both for cells and the emergent ecosystem, is in its infancy. To advance this understanding, we analyzed the lipid, metabolite, and protein content of vesicles produced by two strains of the most abundant phytoplankton cell in the ocean, the cyanobacterium Prochlorococcus. We show that Prochlorococcus exports an enormous array of cellular compounds into their surroundings via extracellular vesicles. The vesicles produced by the two different strains contained some materials in common, but also displayed numerous strain-specific differences, reflecting functional complexity within natural vesicle populations. Prochlorococcus vesicles contain active enzymes, indicating that they can mediate biogeochemically relevant extracellular reactions in the wild. Interaction assays demonstrate that vesicles from Prochlorococcus and multiple genera of heterotrophic bacteria can associate with other marine microbes, including Pelagibacter, the most abundant heterotrophic group in the oceans. Our observations suggest that vesicles may play diverse functional roles in the oceans, including but not limited to mediating energy and nutrient transfers, catalyzing extracellular biochemical reactions, and mitigating toxicity of reactive oxygen species. These findings further indicate that a portion of the ‘dissolved’ compounds in the oceans are not truly dissolved, but are instead packaged within locally structured, colloidal vesicles.

Project description:Rates of production and degradation together specify microRNA (miRNA) abundance and dynamics. Here, we used approach-to-steady-state metabolic labeling to assess these rates for 176 miRNAs in contact-inhibited mouse embryonic fibroblasts (MEFs), 182 miRNAs in dividing MEFs, and 127 miRNAs in mouse embryonic stem cells (mESCs). MicroRNA duplexes, each comprising a mature miRNA and its passenger strand, are produced at rates as fast as 110 ± 50 copies/cell per min, which exceeds rates reported for any mRNAs. These duplexes are rapidly loaded into Argonaute, with < 10 min typically required for duplex loading and silencing-complex maturation. Within Argonaute, guide strands have stabilities that vary by 100-fold. Half-lives also vary globally between cell lines, with median values ranging from 11 to 34 h in mESCs and contact-inhibited MEFs, respectively. Moreover, relative half-lives for individual miRNAs vary between cell types, implying the influence of cell-specific factors in dictating turnover rate. The apparent influence of miRNA regions most important for targeting, together with the effect of one target on miR-7 accumulation, suggest that targets fulfill this role. Analysis of the tailing and trimming of miRNA 3 termini showed that the flux was typically greatest through the isoform tailed with a single uridine, although changes in this flux did not correspond to changes in stability, which suggested that the processes of tailing and trimming might be independent from that of decay. Together these results establish a framework for describing the dynamics and regulation of miRNAs throughout their lifecycle.

Project description:Prochlorococcus is a genus of abundant and ecologically important marine cyanobacteria. Here, we present the comprehensive comparison of the structure and composition of the transcriptomes of two closely related Prochlorococcus strains, which, despite their similarities, have adapted their gene pool to specific environmental constraints. We used large-scale strand-specific cDNA sequencing, microarray RNA profiling and computational analyses to characterize the transcriptomes of Prochlorococcus sp. MED4 and Prochlorococcus sp. MIT9313, representatives of the two major ecotypes adapted to high and low light conditions, respectively. We present genome-wide maps of transcriptional start sites (TSS) for both organisms. Our data suggest antisense transcription for three quarters of all genes. A direct comparison revealed very little conservation in the use of TSS and the nature of non-coding transcripts between both strains. We conclude that the major transcriptional output from these highly streamlined genomes consists of antisense RNA and that a hitherto unrecognized high degree of variability exists in the transcriptional architecture of these rapidly evolving prokaryotes. Furthermore, we detected extremely short 5’ untranslated regions with a median length of only 27 nt and 29 nt for MED4 and MIT9313, respectively, and noticed the absence of the Shine-Dalgarno motif, which is suggestive of alternative mechanisms for the initiation of translation. For 8 % of all protein-coding genes, the median length to the initiator codon is 10 nt or shorter, suggesting that leaderless translation and ribosomal protein S1-dependent translation constitute the primary avenues for protein synthesis in Prochlorococcus.