Project description:The C-terminal domain (CTD) of the largest subunit in DNA-dependent RNA polymerase II (RNAP II) is essential for mRNA syntheses, coordinating an astounding array of protein-protein interactions. In yeast, mutations that separate established functional units of the CTD result in pleiotrophic effects, producing slow growth phenotypes and the accumulation of abnormally large cells. In general, the downstream pathways for such CTD related phenotypes are uncharacterized and probably highly complex. We also observed that a sizeable fraction of CTD mutants retain multiple buds on parent cells and are elongated relative to wild-type yeast. FACScan analyses revealed a trend toward increased DNA content over multiple rounds of growth, indicating that insertions into the normal tandemly repeated CTD result in aneuploidy. To begin to address the role of the CTD in such complex changes in cell structure and behavior, we applied an integrated approach using the Saccharomyces cerevisiae Genome Database (SGD) and microarray data. We were able to identify candidate genetic networks that could explain chromosome missegregation and related phenotypic traits in CTD mutants. These networks provide links between CTD-associated proteins and kinetochore function, control of cell cycle checkpoint mechanisms, and expression of cell wall and membrane components. The essential elements required for CTD function have been determined in yeast though substitution and insertion mutations (West and Corden 1995; Stiller and Cook 2004; Liu et al. 2008); the core CTD functional unit lies within tandem heptapeptides or â??diheptadsâ??. In addition, CTD mutants with progressively longer polyalanine insertions between diheptads show a continuous decline in growth rates, and the induction of conditional phenotypes; this has been demonstrated out to five alanine (5A) insertions (Stiller and Cook, 2004). Attempts to restore the global amino acid register via extending insertions to seven alanines between diheptad units proved to be lethal, leading to the conclusion that too great a separation between functional units puts undo stress on at least some essential CTD-protein interactions. (Liu et al, 2008). During these prior investigations, we observed that mutants containing 5A insertions are, on average, twice as large as normal yeast, prompting us to investigate these cells in more detail. Yeast cells were transformed with mutated CTD sequences containing 5 alanine insertions between diheptad units via the plasmid shuffle, as described in detail previously (West and Corden 1995; Stiller and Cook 2004). For comparison yeast cells were transformed with YSPTSPS sequences via the plasmid shuffle, as described in detail previously (West and Corden 1995; Stiller and Cook 2004). RNA was extracted from fresh pellets of yeast cultures at log phase, grown to an optical density of 0.8 at 600nm in 100 ml of YPD medium (1% yeast extract, 2% peptone, and 2% dextrose) at 30 ºC in a shaker at 225 rpm. Total RNA was extracted using Qiagenâ??s RNeasy Kit (Valencia, CA). Four replicates for each sample yeast strain (5A and wild-type CTD control) were prepared, and 10ug total RNA for every replicates were sent to Duke university DNA microarray center for further analyses. Array ID YO06N from Operon Yeast Genome Oligo Set version 1.1.2 was used for the hybridization. The direct labeling protocol was performed for sample RNA, which included steps of first strand synthesis, slide preparation, hydrolysis, cDNA purification, hybridization and array washing. Cy3 and Cy5 were used for labeling the samples. Maui hybridization and TIGR washing system were used in this protocol for array hybridization and washing respectively. The protocol can be found in Duke University microarray center website as http://www.genome.duke.edu/cores/microarray/services/spotted-arrays/protocols/. Fluorescent DNA bound to the microarray was detected with a GenePix 4000B scanner (Axon Instruments, Foster city, CA), using the GenePix 4000 software package to locate signal from spots. Data processing was performed using Duke Univerisity BASE web server (https://base-server.duhs.duke.edu/). GO annotation was used for gene ontology.

Project description:The C-terminal domain (CTD) of the largest subunit of RNA polymerase II (RNAP II) consists of repeated YSPTSPS heptapeptides and connects transcription with cotranscriptional events. Threonine-4 (Thr4) of the CTD repeats has been shown to function in histone mRNA 3'-end processing in chicken cells and in transcriptional elongation in human cells. Here, we demonstrate that, in budding yeast, Thr4, although dispensable for growth in rich media, is essential in phosphate-depleted or galactose-containing media. Thr4 is required to maintain repression of phosphate-regulated (PHO) genes under normal growth conditions and for full induction of PHO5 and the galactose-induced GAL1 and GAL7 genes. We identify genetic links between Thr4 and the histone variant Htz1 and show that Thr4, as well as the Ino80 chromatin remodeler, is required for activation-associated eviction of Htz1 specifically from promoters of the Thr4-dependent genes. Our study uncovers a connection between transcription and chromatin remodeling linked by Thr4 of the CTD. RNA-seq of wild type and T4V mutant of budding yeast RNAP II CTD in duplicates

Project description:This RNA-Seq analysis compares gene expression of the RNA polymerase II CTD-mutants contrasting to the WT RNA polymerase II CTD (with isogenic 3' selection marker) in the fission yeast S. pombe

Project description:This RNA-Seq analysis compares gene expression of the suppressors of RNA polyemrase II CTD-T4A (STF6 and STF9 mutants) contrasting to the parental RNA polymerase II CTD-T4A mutant in the fission yeast S. pombe

Project description:The C-terminal domain (CTD) of the largest subunit of RNA polymerase II (RNAP II) consists of repeated YSPTSPS heptapeptides and connects transcription with cotranscriptional events. Threonine-4 (Thr4) of the CTD repeats has been shown to function in histone mRNA 3'-end processing in chicken cells and in transcriptional elongation in human cells. Here, we demonstrate that, in budding yeast, Thr4, although dispensable for growth in rich media, is essential in phosphate-depleted or galactose-containing media. Thr4 is required to maintain repression of phosphate-regulated (PHO) genes under normal growth conditions and for full induction of PHO5 and the galactose-induced GAL1 and GAL7 genes. We identify genetic links between Thr4 and the histone variant Htz1 and show that Thr4, as well as the Ino80 chromatin remodeler, is required for activation-associated eviction of Htz1 specifically from promoters of the Thr4-dependent genes. Our study uncovers a connection between transcription and chromatin remodeling linked by Thr4 of the CTD.

Project description:In fission yeast, the nuclear-localized Lsk1p-Lsc1p-Lsg1p cyclin dependent kinase complex is required for the reliable execution of cytokinesis and is also required for Ser-2 phosphorylation RNA pol II carboxy terminal domain. To address whether alterations in CTD phosphorylation might selectively alter expression of cytokinesis genes, expression profiling of site-directed CTD mutants was performed.

Project description:Ctk1 + CTD mutants

Project description:Transcriptional profiling of fission yeast RNA polymerase II CTD mutants

Project description:We profiled total-mRNA from yeast cells grown in identical conditions to match samples submitted for proteome-wide absolute quantification. Matching mRNA profiles to absolute protein copies numbers enables a more accurate comparison of transcript to final protein levels. Here we were able to show direct comparison results in a correlation of Rsquared of 0.58, show suggesting as much as ~40% of final protein levels in yeast cannot be determined from mRNA levels alone. Reads were mapped to a reference genome of S. cerevisiae, downloaded from the Saccharomyces Genome Database (SGD), using Bowtie version 1 (74). Mapped sequences were then assembled into transcripts and quantified using Cufflinks version 2.0 (75) (using the SGD reference genome GTF file).

Project description:RNA Polymerase V transcription recruits siRNA-Argonaute protein complexes to chromatin, thereby specifying sites of RNA-directed DNA methylation (RdDM) and transcriptional gene silencing in plants. The Pol V largest subunit, NRPE1, has an extensive carboxyl-terminal domain (CTD) that is dispensable for catalytic activity in vitro, yet essential in vivo. A CTD subdomain, DeCL, named for its similarity to a chloroplast protein, DEFECTIVE CHLOROPLASTS AND LEAVES, is required for Pol V function at virtually all loci, similar to mutants defective for Pol V recruitment. Deletions removing three other CTD subdomains affect overlapping subsets of loci, similar to mutants lacking proteins that bind Pol V or its transcripts. A yeast two-hybrid screen for CTD-interactors identified the 3-prime -> 5-prime exoribonuclease, RRP6L1 as an interactor with the DeCL subdomain and the adjacent QS subdomain, named for its numerous glutamine-serine (QS) repeats. These RRP6L1-binding subdomains immediately follow the Argonaute-binding subdomain. Experimental evidence indicates that RRP6L1 trims the 3-prime ends of Pol V transcripts sliced by ARGONAUTE 4 (AGO4), suggesting a model whereby the adjacent CTD subdomains enable the spatial and temporal coordination of AGO4 and RRP6L1 RNA processing activities.