Project description:Transcription by RNA polymerase I (RNAPI) represents the majority of the transcriptional activity in eukaryotic cells and is associated with the production of mature ribosomal rRNAs (rRNAs). As several rRNA maturation steps are coupled to RNAPI transcription, the rate of RNAPI elongation directly influences processing of nascent rRNA, and changes in RNAPI transcription rate can result in alternative rRNA processing pathways in response to growth conditions and stress. However, factors and mechanisms that control RNAPI progression by influencing transcription elongation rate remain poorly understood. We show here that the conserved fission yeast RNA-binding protein Seb1 associates with the RNAPI transcription machinery and promotes RNAPI pausing states along the rDNA. The overall faster progression of RNAPI at the rDNA in Seb1-deficient cells impaired cotranscriptional rRNA processing and the production of mature rRNAs. Given that Seb1 also influences pre-mRNA processing by modulating RNAPII progression, our findings unveil Seb1 as a pausing-promoting factor for RNA polymerases I and II to control cotranscriptional RNA processing.

Project description:Cell growth is well defined for the late (post-embryonic) stages of development, but evidence for early (embryonic) cell growth during post-mitotic morphogenesis is quite limited. Here, we identify early cell growth as a key characteristic of Drosophila embryonic salivary gland (SG) tubulogenesis. A BTB/POZ domain nuclear factor, Ribbon (Rib), mediates early cell growth without affecting endoreplication. Rib binds the transcription start site of nearly every SG-expressed ribosomal protein gene (RPG), and is required for full expression of all RPGs tested. Rib binding to RPG enhancers is, however, weak and not sequence-specific, suggesting that specificity is achieved through co-factor interactions. We demonstrate Rib’s ability to physically interact with each of the three known activators of RPG transcription. Surprisingly, Rib-dependent early cell growth in another tubular organ—the embryonic trachea—is not mediated by direct RPG transcription. Our results support a model for tissue-specific transcriptional regulation in early cell growth programs.

Project description:Rph1 coordinates transcription of ribosomal protein gene and ribosomal RNA to control cell growth under nutrient stress conditions

Project description:Heterozygous inactivating mutations in ribosomal protein genes (RPGs) are associated with hematopoietic and developmental abnormalities, activation of p53, and altered risk of cancer in humans and model organisms. As a part of a large-scale study aimed at identifying associations between RPG deletions, p53 activation, and perturbations of rRNA maturation patterns, we analyzed a series of blood and bone marrow samples from children with acute lymphoblastic leukemia (ALL), as a baseline genomic characterization.

Project description:In yeast, ribosome production is controlled transcriptionally by tight coregulation of the 138 ribosomal protein genes (RPGs). RPG promoters display limited sequence homology, and the molecular basis for their coregulation remains largely unknown. Here we identify two prevalent RPG promoter types, both characterized by upstream binding of the general transcription factor (TF) Rap1 followed by the RPG-specific Fhl1/Ifh1 pair, with one type also binding the HMG-B protein Hmo1. We show that the regulatory properties of the two promoter types are remarkably similar, suggesting that they are determined to a large extent by Rap1 and the Fhl1/Ifh1 pair. Rapid depletion experiments allowed us to define a hierarchy of TF binding in which Rap1 acts as a pioneer factor required for binding of all other TFs. We also uncovered unexpected features underlying recruitment of Fhl1, whose forkhead DNA-binding domain is not required for binding at most promoters, and Hmo1, whose binding is supported by repeated motifs. Finally, we describe unusually micrococcal nuclease (MNase)-sensitive nucleosomes at all RPG promoters, located between the canonical +1 and M-bM-^@M-^S1 nucleosomes, which coincide with sites of Fhl1/Ifh1 and Hmo1 binding. We speculate that these M-bM-^@M-^XM-bM-^@M-^XfragileM-bM-^@M-^YM-bM-^@M-^Y nucleosomes play an important role in regulating RPG transcriptional output. Genome-wide examination of binding sites for transcription factors controlling ribosomal protein genes expression and nucleosome positions in budding yeast cells

Project description:Determination of RNAPII, Rrd1-Myc, RNAPII-Ser2-P, RNAPII-Ser5-P abundance between wildtype and rrd1 deletion strains under rapamycin or control treatments.Rapamycin is an anticancer agent and immunosuppressant that acts by inhibiting the TOR signaling pathway. In yeast, rapamycin mediates a profound transcriptional response for which the RRD1 gene is required. To further investigate this connection, we performed genome-wide association studies of RNA polymerase II (RNAPII) and Rrd1 in response to rapamycin and demonstrate that Rrd1 colocalizes with RNAPII on actively transcribed genes and both are recruited to rapamycin responsive genes. Strikingly, when Rrd1 is lacking, RNAPII remains inappropriately associated to ribosomal genes and fails to be recruited to rapamycin responsive genes. This occurs independently of TATA box binding protein recruitment. Furthermore, Rrd1 modulates the phosphorylation status of RNAPII CTD and additional evidence suggests that Rrd1 is involved in various transcriptional stress responses. We propose that Rrd1 is a novel transcription elongation factor that fine-tunes the transcriptional stress response of RNAPII.

Project description:Cells respond to environmental signals by alteration of gene expression through action of transcription factors. A JmjC-domain-containing protein Rph1 belongs to the C2H2 zinc finger protein family and functions to repress transcription of PHR1 via histone demethylation. However, additional targets of Rph1 remain largely unknown. Here, we investigate the regulatory network of Rph1 by microarray analyses. More than 75% of Rph1-regulated genes showed increased expression in rph1M-NM-^T, suggesting Rph1 serves as a transcriptional repressor under physiological conditions. The binding motif of Rph1 resembling the STress Response Element (STRE) was over-represented in the promoters of Rph1-repressed genes. In addition, significant proportions of Rph1-regulated genes responded to DNA damage and environmental stress, implying a repressive role of Rph1 in the cross-protection of stress responses. We used expression microarray to identify Rph1-regulated genes and established Rph1 functioned as a transcriptional repressor to link DNA damage signaling and general stress response. We compared gene expression in wild-type and rph1-deleted strains cultured in rich medium (YPD) during exponential growth. 3 biological samples were analyzed.

Project description:In yeast, ribosome production is controlled transcriptionally by tight coregulation of the 138 ribosomal protein genes (RPGs). RPG promoters display limited sequence homology, and the molecular basis for their coregulation remains largely unknown. Here we identify two prevalent RPG promoter types, both characterized by upstream binding of the general transcription factor (TF) Rap1 followed by the RPG-specific Fhl1/Ifh1 pair, with one type also binding the HMG-B protein Hmo1. We show that the regulatory properties of the two promoter types are remarkably similar, suggesting that they are determined to a large extent by Rap1 and the Fhl1/Ifh1 pair. Rapid depletion experiments allowed us to define a hierarchy of TF binding in which Rap1 acts as a pioneer factor required for binding of all other TFs. We also uncovered unexpected features underlying recruitment of Fhl1, whose forkhead DNA-binding domain is not required for binding at most promoters, and Hmo1, whose binding is supported by repeated motifs. Finally, we describe unusually micrococcal nuclease (MNase)-sensitive nucleosomes at all RPG promoters, located between the canonical +1 and –1 nucleosomes, which coincide with sites of Fhl1/Ifh1 and Hmo1 binding. We speculate that these ‘‘fragile’’ nucleosomes play an important role in regulating RPG transcriptional output.

Project description:Anti-sense non-coding transcripts, genes-within-genes, and convergent gene pairs are prevalent among eukaryotes. The existence of such transcription units raises the question of what happens when RNA polymerase II (RNAPII) molecules collide head-to-head. Here we use a combination of biochemical and genetic approaches in yeast to show that polymerases transcribing opposite DNA strands cannot bypass each other. RNAPII stops, but does not dissociate upon head-to-head collision in vitro, suggesting that opposing polymerases represent insurmountable obstacles for each other. Head-to-head collision in vivo results in RNAPII stopping as well, and removal of collided RNAPII from the DNA template can be achieved via ubiquitylation-directed proteolysis. Indeed, in cells lacking efficient RNAPII poly-ubiquitylation, the half-life of collided polymerases increases, so that these can be detected between convergent genes by ChIP-Seq. These results provide new insight into fundamental mechanisms of gene traffic control, and point to an unexplored effect of anti-sense transcription on gene regulation via polymerase collision. Total RNA was extracted from WT or Elongin C deletion mutant (elc1M-bM-^HM-^F) cells and strand-specific RNA-Seq was performed. Three biological replicates were performed for WT and elc1M-bM-^HM-^F.

Project description:Anti-sense non-coding transcripts, genes-within-genes, and convergent gene pairs are prevalent among eukaryotes. The existence of such transcription units raises the question of what happens when RNA polymerase II (RNAPII) molecules collide head-to-head. Here we use a combination of biochemical and genetic approaches in yeast to show that polymerases transcribing opposite DNA strands cannot bypass each other. RNAPII stops, but does not dissociate upon head-to-head collision in vitro, suggesting that opposing polymerases represent insurmountable obstacles for each other. Head-to-head collision in vivo results in RNAPII stopping as well, and removal of collided RNAPII from the DNA template can be achieved via ubiquitylation-directed proteolysis. Indeed, in cells lacking efficient RNAPII poly-ubiquitylation, the half-life of collided polymerases increases, so that these can be detected between convergent genes by ChIP-Seq. These results provide new insight into fundamental mechanisms of gene traffic control, and point to an unexplored effect of anti-sense transcription on gene regulation via polymerase collision. ChIP-Seq of RNA polymerase II was performed with WT and Elongain C deletion mutant (elc1M-bM-^HM-^F) cells. 4H8 antibody against the Rpb1 C-terminal domain was used for RNA polymerase II immunoprecipitation, whilst mouse IgG antibody was used for control immunoprecipitations. Two biological replicates were performed for both WT and elc1M-bM-^HM-^F.