Project description:When C. elegans larvae hatch in the absence of food they persist in a stress resistant, developmentally arrested state (L1 arrest) for weeks or until food becomes available. We characterized growth, mRNA expression, and RNA Polymerase II activity genome-wide during L1 arrest and recovery. RNA Pol II binding data resulting from ChIP-Seq experiments using the Illumina Genome Analyzer are included in this GEO submission. Complementary mRNA expression data from the Affymetrix microarray platform can be found at GEO accession# GSE11055. The goals of the Pol II ChIP-Seq compononent of this project were to use Pol II antibodies 1) to investigate patterns of transcription in developmentally arrested larvae, when mRNA expression levels have reached steady state; 2) to investigate patterns of transcription in immediate response to feeding, when mRNA expression levels change dramatically; and 3) to investigate accumulation of Pol II at promoters during arrest and recovery. We started our ChIP studies with the S2 antibody (Abcam ab5095) since it was raised against a Ser2 phosphorylated peptide from the C-terminal domain of Pol II and should therefore be relatively specific for active, elongating Pol II, and it worked well for the first two goals above. In order to investigate accumulation of Pol II at promoters, we used the S2 antibody and complemeted it with antibody 4H8 (Abcam ab5408), which according to the manafacturer recognizes phosphorylated and non-phosphorylated Pol II, and antibody 8WG16 (Abcam ab817), which binds primarily to non-phosphorylated Pol II but also relatively weakly to phosphorylated Pol II. We were somewhat surprised to find that the results obtained with each of these antibodies were very similar, though upon deeper analysis we discovered relatively subtle differences consistent with the relative specificities of each antibody and existing models regarding phosphorylation state of Pol II and its activity and location. In summary, we find that while Pol II continues transcribing starvation genes, it is M-bM-^@M-^XpausedM-bM-^@M-^Y accumulates on the promoters of growth and development genes during L1 arrest. Consistent with it poising arrested larvae for recovery, pausingpromoter accumulation decreases in response to feeding, while elongation and mRNA levels increase. These results demonstrate that Pol II pausing is widespread in C. elegans and that it is nutritionally controlled during development.These results demonstrate that accumulation of Pol II at promoters of growth and development genes is common in C. elegans and that promoter accumulation anticipates nutritionally controlled gene expression during development. RNA Pol II binding was examined with three different antibodies (S2, 4H8, and 8WG16) during either L1 arrest (starvation) or after 1 hr recovery by feeding. For the S2 antibody two different time points during L1 arrest were examined (6 and 12 hr). 14 total samples are included: 4 independent control samples (Input), a pair biological replicates with the S2 antibody at 6 hr L1 arrest, a pair of biological replicates with the 4H8 antibody at 12 hr L1 arrest and at 1 hr recovery, and singletons for the S2 and 8WG16 antibodies at 12 hr L1 arrest and at 1 hr recovery. "GSE13973_PolII_ChIP-Seq.xls.gz" contains 5 worksheets with the following contents: "geneDensity" includes the number of reads per million mapping to each gene model normalized to gene length. Units are reads per million per kilobase. "TSSdensity" includes the number of reads per million mapping to a 200 bp window spanning the most upstream transcription start site for each gene and normalized by length (200 bp). Units are reads per million per kilobase. "geneEnrichment" includes the fold-enrichment of read density over each gene model relative to input. Where input values were below the median of all input values then the median was used. Units are fold-enrichment. "TSSenrichment" includes the fold-enrichment of read density over the 200 bp TSS window relative to input. Where input values were below the median of all input values then the median was used. Units are fold-enrichment. "5' bias" includes 5' bias calculation for each gene and each antibody in each condition. "GSE13973_CelegansWS190_GeneCoordinates.xls.gz" contains the gene coordinates based on version WS190 of the C. elegans genome.
Project description:When C. elegans larvae hatch in the absence of food they persist in a stress resistant, developmentally arrested state (L1 arrest) for weeks or until food becomes available. We characterized growth, mRNA expression, and RNA Polymerase II activity genome-wide during L1 arrest and recovery. RNA Pol II binding data resulting from ChIP-Seq experiments using the Illumina Genome Analyzer are included in this GEO submission. Complementary mRNA expression data from the Affymetrix microarray platform can be found at GEO accession# GSE11055. The goals of the Pol II ChIP-Seq compononent of this project were to use Pol II antibodies 1) to investigate patterns of transcription in developmentally arrested larvae, when mRNA expression levels have reached steady state; 2) to investigate patterns of transcription in immediate response to feeding, when mRNA expression levels change dramatically; and 3) to investigate accumulation of Pol II at promoters during arrest and recovery. We started our ChIP studies with the S2 antibody (Abcam ab5095) since it was raised against a Ser2 phosphorylated peptide from the C-terminal domain of Pol II and should therefore be relatively specific for active, elongating Pol II, and it worked well for the first two goals above. In order to investigate accumulation of Pol II at promoters, we used the S2 antibody and complemeted it with antibody 4H8 (Abcam ab5408), which according to the manafacturer recognizes phosphorylated and non-phosphorylated Pol II, and antibody 8WG16 (Abcam ab817), which binds primarily to non-phosphorylated Pol II but also relatively weakly to phosphorylated Pol II. We were somewhat surprised to find that the results obtained with each of these antibodies were very similar, though upon deeper analysis we discovered relatively subtle differences consistent with the relative specificities of each antibody and existing models regarding phosphorylation state of Pol II and its activity and location. In summary, we find that while Pol II continues transcribing starvation genes, it is ‘paused’ accumulates on the promoters of growth and development genes during L1 arrest. Consistent with it poising arrested larvae for recovery, pausingpromoter accumulation decreases in response to feeding, while elongation and mRNA levels increase. These results demonstrate that Pol II pausing is widespread in C. elegans and that it is nutritionally controlled during development.These results demonstrate that accumulation of Pol II at promoters of growth and development genes is common in C. elegans and that promoter accumulation anticipates nutritionally controlled gene expression during development.
Project description:Fluctuations in nutrient availability profoundly impact gene expression. Previous work revealed post-recruitment regulation of RNA Polymerase II (Pol II) during starvation and recovery in Caenorhabitis elegans, suggesting promoter-proximal pausing promotes rapid response to feeding. To test this hypothesis, we measured Pol II elongation genome-wide by two complementary approaches and analyzed elongation in conjunction with Pol II binding and expression. We confirmed bona fide pausing during starvation and also discovered Pol II docking. Pausing occurs at active stress-response genes that become down-regulated in response to feeding. In contrast M-bM-^@M-^\dockedM-bM-^@M-^] Pol II accumulates without initiating upstream of inactive growth genes that become rapidly up-regulated upon feeding. Beyond differences in function and expression, these two sets of genes have different core promoter motifs, suggesting alternative transcriptional machinery. Our work suggests that growth and stress genes are both regulated post-recruitment during starvation, but at initiation and elongation, respectively, coordinating gene expression with nutrient availability. We sequenced short, capped RNA (scRNA-seq) from N2 starved L1 C. elegans as well as a TFIIS mutant (RB2083). We also prepared scRNA-seq libraries from L1 larvae using one, two, or three of the enymes used to prepare the scRNA sequencing libraries as well as scRNA-seq libraries from Drosophila S2 cells using one or two of the enzymes. We further sequenced the 5' end of mRNA in starved C. elegans L1 larvae using the same enzymes as scRNA-seq.
Project description:Expression data from Caenorhabditis elegans let-418(RNAi), mep-1(RNAi) and gfp(RNAi) L1 larvae. The C. elegans genome encodes two homologs of the human protein Mi-2, namely LET-418 and CHD-3. LET-418 plays an essential role during development; its depletion leads to a pleiotropic and lethal phenotype that includes larval arrest, an everted vulva and sterility. Without maternal contribution, let-418 mutants stop their development at the L1 larval stage (von Zelewsky et al., 2000). We further characterized this arrest and showed that it is very similar to the L1 diapause induced by starvation; both germline and somatic cells remain in a quiescent state in let-418 L1 arrested larvae, indicating that LET-418 activity is required to bypass the L1 arrest in presence of food. The let-418 L1 larvae express ectopically the P granule component PGL-1 in somatic cells (Unhavaithaya et al., 2002). Interestingly, the phenotype of mep-1 mutants is remarkably similar to that of let-418: RNAi targeting mep-1 also induced an L1 arrest phenotype; furthermore, MEP-1 and LET-418 have been shown to physically interact (Unhavaithaya et al., 2002 and M. Passannante). The null allele mep-1(q660) is temperature sensitive and shows a more severe phenotype at higher temperatures. At 20°C, about 10% of mep-1 homozygotes derived from heterozygous mothers arrest as young larvae, whereas the remaining 90% develop into sterile adults (Belfiore et al., 2002). Later in development, the somatic gonad is affected in mep-1(q660) mutants. This results in an abnormal and disorganized gonad, a phenotype also observed in let-418(s1617) mutants. Both let-418 and mep-1 mutants produce a very limited number of oocytes and have pseudovulvae derived from P8.p (Belfiore et al., 2002; von Zelewsky et al., 2000 and C. Wicky, personal communication). Preliminary quantitative real-time PCR revealed that the expression of genes coding for P granule components was deregulated in both mep-1(RNAi) and let-418(RNAi) L1 larvae (data not shown). To further investigate this issue, we performed a complete gene expression analysis. Given the fact that mep-1(q660) mutants are sterile, we used RNA interference to generate mep-1 depleted worms. Bacteria expressing gfp dsRNA (pPE128.110 in HT115) were used as reference, since RNA interference may induce gene expression changes by itself. C. elegans L1 larvae treated with RNA interference were selected for RNA extraction and hybridization on Affymetrix microarrays. Synchronized wild type L4 animals were grown at 25° on bacteria expressing either gfp, let-418 or mep-1 dsRNA. Eggs were collected by bleaching gravid adults and allowed to hatch in the absence of food at 25°C. Newly hatched L1 larvae were fed on bacteria expressing the different dsRNA for three hours to recover from starvation. Three replicates per RNAi.
Project description:We acquired RNA Polymerase II (POL II) binding profiles at embyonic and starved L1 stages in pha-4 transgenic worms. Transcription factor gene pha-4 was tagged with GFP and their expression examined throughout the C. elegans life cycle. The POL II occupancy were determined using chromatin immunoprecipitation with anti-POL II antibodies followed by illumina high-throughput sequencing (ChIP-seq). For data usage terms and conditions, please refer to http://www.genome.gov/27528022 and http://www.genome.gov/Pages/Research/ENCODE/ENCODEDataReleasePolicyFinal2008.pdf
Project description:Expression data from Caenorhabditis elegans let-418(RNAi), mep-1(RNAi) and gfp(RNAi) L1 larvae. The C. elegans genome encodes two homologs of the human protein Mi-2, namely LET-418 and CHD-3. LET-418 plays an essential role during development; its depletion leads to a pleiotropic and lethal phenotype that includes larval arrest, an everted vulva and sterility. Without maternal contribution, let-418 mutants stop their development at the L1 larval stage (von Zelewsky et al., 2000). We further characterized this arrest and showed that it is very similar to the L1 diapause induced by starvation; both germline and somatic cells remain in a quiescent state in let-418 L1 arrested larvae, indicating that LET-418 activity is required to bypass the L1 arrest in presence of food. The let-418 L1 larvae express ectopically the P granule component PGL-1 in somatic cells (Unhavaithaya et al., 2002). Interestingly, the phenotype of mep-1 mutants is remarkably similar to that of let-418: RNAi targeting mep-1 also induced an L1 arrest phenotype; furthermore, MEP-1 and LET-418 have been shown to physically interact (Unhavaithaya et al., 2002 and M. Passannante). The null allele mep-1(q660) is temperature sensitive and shows a more severe phenotype at higher temperatures. At 20°C, about 10% of mep-1 homozygotes derived from heterozygous mothers arrest as young larvae, whereas the remaining 90% develop into sterile adults (Belfiore et al., 2002). Later in development, the somatic gonad is affected in mep-1(q660) mutants. This results in an abnormal and disorganized gonad, a phenotype also observed in let-418(s1617) mutants. Both let-418 and mep-1 mutants produce a very limited number of oocytes and have pseudovulvae derived from P8.p (Belfiore et al., 2002; von Zelewsky et al., 2000 and C. Wicky, personal communication). Preliminary quantitative real-time PCR revealed that the expression of genes coding for P granule components was deregulated in both mep-1(RNAi) and let-418(RNAi) L1 larvae (data not shown). To further investigate this issue, we performed a complete gene expression analysis. Given the fact that mep-1(q660) mutants are sterile, we used RNA interference to generate mep-1 depleted worms. Bacteria expressing gfp dsRNA (pPE128.110 in HT115) were used as reference, since RNA interference may induce gene expression changes by itself.