Your search keyword '"RNA Polymerase II genetics"' showing total 66 results

1. DNA-directed termination of mammalian RNA polymerase II.

Author

Davidson L, Rouvière JO, Sousa-Luís R, Nojima T, Proudfoot NJ, Jensen TH, and West S

Subjects

Humans, Animals, DNA metabolism, DNA genetics, Promoter Regions, Genetic genetics, Exoribonucleases metabolism, Exoribonucleases genetics, Transcription, Genetic, RNA Polymerase II metabolism, RNA Polymerase II genetics, Transcription Termination, Genetic

Abstract

The best-studied mechanism of eukaryotic RNA polymerase II (RNAPII) transcriptional termination involves polyadenylation site-directed cleavage of the nascent RNA. The RNAPII-associated cleavage product is then degraded by XRN2, dislodging RNAPII from the DNA template. In contrast, prokaryotic RNAP and eukaryotic RNAPIII often terminate directly at T-tracts in the coding DNA strand. Here, we demonstrate a similar and omnipresent capability for mammalian RNAPII. Importantly, this termination mechanism does not require upstream RNA cleavage. Accordingly, T-tract-dependent termination can take place when XRN2 cannot be engaged. We show that T-tracts can terminate snRNA transcription independently of RNA cleavage by the Integrator complex. Importantly, we found genome-wide termination at T-tracts in promoter-proximal regions but not within protein-coding gene bodies. XRN2-dependent termination dominates downstream from protein-coding genes, but the T-tract process is sometimes used. Overall, we demonstrate global DNA-directed attrition of RNAPII transcription, suggesting that RNAPs retain the potential to terminate over T-rich sequences throughout evolution., (© 2024 Davidson et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2024

2. Notch induces transcription by stimulating release of paused RNA polymerase II.

Author

Rogers JM, Mimoso CA, Martin BJE, Martin AP, Aster JC, Adelman K, and Blacklow SC

Subjects

Humans, Signal Transduction genetics, Receptor, Notch1 metabolism, Receptor, Notch1 genetics, Gene Expression Regulation, Cell Line, RNA Polymerase II metabolism, RNA Polymerase II genetics, Transcription, Genetic, Chromatin metabolism, Chromatin genetics

Abstract

Notch proteins undergo ligand-induced proteolysis to release a nuclear effector that influences a wide range of cellular processes by regulating transcription. Despite years of study, however, how Notch induces the transcription of its target genes remains unclear. Here, we comprehensively examine the response to human Notch1 across a time course of activation using high-resolution genomic assays of chromatin accessibility and nascent RNA production. Our data reveal that Notch induces target gene transcription primarily by releasing paused RNA polymerase II (RNAPII). Moreover, in contrast to prevailing models suggesting that Notch acts by promoting chromatin accessibility, we found that open chromatin was established at Notch-responsive regulatory elements prior to Notch signal induction through SWI/SNF-mediated remodeling. Together, these studies show that the nuclear response to Notch signaling is dictated by the pre-existing chromatin state and RNAPII distribution at the time of signal activation., (© 2024 Rogers et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2024

3. Reorganization of lamina-associated domains in early mouse embryos is regulated by RNA polymerase II activity.

Author

Pal M, Altamirano-Pacheco L, Schauer T, and Torres-Padilla ME

Subjects

Animals, Mice, Embryonic Development genetics, Zygote, Mammals genetics, Gene Expression Regulation, Developmental, Chromatin, RNA Polymerase II genetics, Transcription, Genetic

Abstract

Fertilization in mammals is accompanied by an intense period of chromatin remodeling and major changes in nuclear organization. How the earliest events in embryogenesis, including zygotic genome activation (ZGA) during maternal-to-zygotic transition, influence such remodeling remains unknown. Here, we have investigated the establishment of nuclear architecture, focusing on the remodeling of lamina-associated domains (LADs) during this transition. We report that LADs reorganize gradually in two-cell embryos and that blocking ZGA leads to major changes in nuclear organization, including altered chromatin and genomic features of LADs and redistribution of H3K4me3 toward the nuclear lamina. Our data indicate that the rearrangement of LADs is an integral component of the maternal-to-zygotic transition and that transcription contributes to shaping nuclear organization at the beginning of mammalian development., (© 2023 Pal et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2023

4. Xrn2 substrate mapping identifies torpedo loading sites and extensive premature termination of RNA pol II transcription.

Author

Cortazar MA, Erickson B, Fong N, Pradhan SJ, Ntini E, and Bentley DL

Subjects

Cell Nucleus, Exonucleases, RNA, Antisense, RNA Polymerase II genetics, Poly A

Abstract

The exonuclease torpedo Xrn2 loads onto nascent RNA 5'-PO 4 ends and chases down pol II to promote termination downstream from polyA sites. We report that Xrn2 is recruited to preinitiation complexes and "travels" to 3' ends of genes. Mapping of 5'-PO 4 ends in nascent RNA identified Xrn2 loading sites stabilized by an active site mutant, Xrn2(D235A). Xrn2 loading sites are approximately two to 20 bases downstream from where CPSF73 cleaves at polyA sites and histone 3' ends. We propose that processing of all mRNA 3' ends comprises cleavage and limited 5'-3' trimming by CPSF73, followed by handoff to Xrn2. A similar handoff occurs at tRNA 3' ends, where cotranscriptional RNase Z cleavage generates novel Xrn2 substrates. Exonuclease-dead Xrn2 increased transcription in 3' flanking regions by inhibiting polyA site-dependent termination. Surprisingly, the mutant Xrn2 also rescued transcription in promoter-proximal regions to the same extent as in 3' flanking regions. eNET-seq revealed Xrn2-mediated degradation of sense and antisense nascent RNA within a few bases of the TSS, where 5'-PO 4 ends may be generated by decapping or endonucleolytic cleavage. These results suggest that a major fraction of pol II complexes terminates prematurely close to the start site under normal conditions by an Xrn2-mediated torpedo mechanism., (© 2022 Cortazar et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2022

5. The Pol II preinitiation complex (PIC) influences Mediator binding but not promoter-enhancer looping.

Author

Sun F, Sun T, Kronenberg M, Tan X, Huang C, and Carey MF

Subjects

Animals, Mediator Complex genetics, Mediator Complex metabolism, Mice, Promoter Regions, Genetic genetics, Transcription, Genetic, RNA Polymerase II genetics, RNA Polymerase II metabolism, Transcription Factor TFIID genetics

Abstract

Knowledge of how Mediator and TFIID cross-talk contributes to promoter-enhancer (P-E) communication is important for elucidating the mechanism of enhancer function. We conducted an shRNA knockdown screen in murine embryonic stem cells to identify the functional overlap between Mediator and TFIID subunits on gene expression. Auxin-inducible degrons were constructed for TAF12 and MED4, the subunits eliciting the greatest overlap. Degradation of TAF12 led to a dramatic genome-wide decrease in gene expression accompanied by destruction of TFIID, loss of Pol II preinitiation complex (PIC) at promoters, and significantly decreased Mediator binding to promoters and enhancers. Interestingly, loss of the PIC elicited only a mild effect on P-E looping by promoter capture Hi-C (PCHi-C). Degradation of MED4 had a minor effect on Mediator integrity but led to a consistent twofold loss in gene expression, decreased binding of Pol II to Mediator, and decreased recruitment of Pol II to the promoters, but had no effect on the other PIC components. PCHi-C revealed no consistent effect of MED4 degradation on P-E looping. Collectively, our data show that TAF12 and MED4 contribute mechanistically in different ways to P-E communication but neither factor appears to directly control P-E looping, thereby dissociating P-E communication from physical looping., (© 2021 Sun et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2021

6. Protein phosphatases in the RNAPII transcription cycle: erasers, sculptors, gatekeepers, and potential drug targets.

Author

Cossa G, Parua PK, Eilers M, and Fisher RP

Subjects

Animals, Drug Delivery Systems, Humans, Phosphoprotein Phosphatases genetics, Phosphoprotein Phosphatases metabolism, RNA Polymerase II genetics, Transcription, Genetic genetics

Abstract

The transcription cycle of RNA polymerase II (RNAPII) is governed at multiple points by opposing actions of cyclin-dependent kinases (CDKs) and protein phosphatases, in a process with similarities to the cell division cycle. While important roles of the kinases have been established, phosphatases have emerged more slowly as key players in transcription, and large gaps remain in understanding of their precise functions and targets. Much of the earlier work focused on the roles and regulation of sui generis and often atypical phosphatases-FCP1, Rtr1/RPAP2, and SSU72-with seemingly dedicated functions in RNAPII transcription. Decisive roles in the transcription cycle have now been uncovered for members of the major phosphoprotein phosphatase (PPP) family, including PP1, PP2A, and PP4-abundant enzymes with pleiotropic roles in cellular signaling pathways. These phosphatases appear to act principally at the transitions between transcription cycle phases, ensuring fine control of elongation and termination. Much is still unknown, however, about the division of labor among the PPP family members, and their possible regulation by or of the transcriptional kinases. CDKs active in transcription have recently drawn attention as potential therapeutic targets in cancer and other diseases, raising the prospect that the phosphatases might also present opportunities for new drug development. Here we review the current knowledge and outstanding questions about phosphatases in the context of the RNAPII transcription cycle., (© 2021 Cossa et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2021

7. Acute perturbation strategies in interrogating RNA polymerase II elongation factor function in gene expression.

Author

Zheng B, Aoi Y, Shah AP, Iwanaszko M, Das S, Rendleman EJ, Zha D, Khan N, Smith ER, and Shilatifard A

Subjects

Cell Cycle Proteins genetics, Cell Cycle Proteins metabolism, Cell Line, Tumor, HCT116 Cells, Heat-Shock Response, Humans, Peptide Elongation Factors genetics, Proteins genetics, Proteins metabolism, RNA Polymerase II genetics, Transcription Factors genetics, Gene Expression genetics, Peptide Elongation Factors metabolism, RNA Polymerase II metabolism, Transcription Factors metabolism

Abstract

The regulation of gene expression catalyzed by RNA polymerase II (Pol II) requires a host of accessory factors to ensure cell growth, differentiation, and survival under environmental stress. Here, using the auxin-inducible degradation (AID) system to study transcriptional activities of the bromodomain and extraterminal domain (BET) and super elongation complex (SEC) families, we found that the CDK9-containing BRD4 complex is required for the release of Pol II from promoter-proximal pausing for most genes, while the CDK9-containing SEC is required for activated transcription in the heat shock response. By using both the proteolysis targeting chimera (PROTAC) dBET6 and the AID system, we found that dBET6 treatment results in two major effects: increased pausing due to BRD4 loss, and reduced enhancer activity attributable to BRD2 loss. In the heat shock response, while auxin-mediated depletion of the AFF4 subunit of the SEC has a more severe defect than AFF1 depletion, simultaneous depletion of AFF1 and AFF4 leads to a stronger attenuation of the heat shock response, similar to treatment with the SEC inhibitor KL-1, suggesting a possible redundancy among SEC family members. This study highlights the usefulness of orthogonal acute depletion/inhibition strategies to identify distinct and redundant biological functions among Pol II elongation factor paralogs., (© 2021 Zheng et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2021

8. Nutrient-dependent control of RNA polymerase II elongation rate regulates specific gene expression programs by alternative polyadenylation.

Author

Yague-Sanz C, Vanrobaeys Y, Fernandez R, Duval M, Larochelle M, Beaudoin J, Berro J, Labbé S, Jacques PÉ, and Bachand F

Subjects

Enzyme Activation drug effects, Genes, Fungal genetics, Mutation, Peptide Chain Elongation, Translational drug effects, Phosphates pharmacology, Polyadenylation, Promoter Regions, Genetic genetics, RNA Polymerase II chemistry, RNA Polymerase II metabolism, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae genetics, Transcription Factors genetics, Gene Expression Regulation drug effects, RNA Polymerase II genetics, Schizosaccharomyces enzymology, Schizosaccharomyces genetics

Abstract

Transcription by RNA polymerase II (RNAPII) is a dynamic process with frequent variations in the elongation rate. However, the physiological relevance of variations in RNAPII elongation kinetics has remained unclear. Here we show in yeast that a RNAPII mutant that reduces the transcription elongation rate causes widespread changes in alternative polyadenylation (APA). We unveil two mechanisms by which APA affects gene expression in the slow mutant: 3' UTR shortening and gene derepression by premature transcription termination of upstream interfering noncoding RNAs. Strikingly, the genes affected by these mechanisms are enriched for functions involved in phosphate uptake and purine synthesis, processes essential for maintenance of the intracellular nucleotide pool. As nucleotide concentration regulates transcription elongation, our findings argue that RNAPII is a sensor of nucleotide availability and that genes important for nucleotide pool maintenance have adopted regulatory mechanisms responsive to reduced rates of transcription elongation., (© 2020 Yague-Sanz et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2020

9. Transcriptional down-regulation of metabolic genes by Gdown1 ablation induces quiescent cell re-entry into the cell cycle.

Author

Jishage M, Ito K, Chu CS, Wang X, Yamaji M, and Roeder RG

Subjects

Animals, Cell Proliferation genetics, Gene Expression Regulation, Developmental genetics, Gene Knockout Techniques, Genes, p53 genetics, Hepatocytes, Liver cytology, Liver metabolism, Signal Transduction genetics, Cell Cycle genetics, Down-Regulation genetics, RNA Polymerase II genetics, RNA Polymerase II metabolism

Abstract

Liver regeneration and metabolism are highly interconnected. Here, we show that hepatocyte-specific ablation of RNA polymerase II (Pol II)-associated Gdown1 leads to down-regulation of highly expressed genes involved in plasma protein synthesis and metabolism, a concomitant cell cycle re-entry associated with induction of cell cycle-related genes (including cyclin D1 ), and up-regulation of p21 through activation of p53 signaling. In the absence of p53, Gdown1-deficient hepatocytes show a severe dysregulation of cell cycle progression, with incomplete mitoses, and a premalignant-like transformation. Mechanistically, Gdown1 is associated with elongating Pol II on the highly expressed genes and its ablation leads to reduced Pol II recruitment to these genes, suggesting that Pol II redistribution may facilitate hepatocyte re-entry into the cell cycle. These results establish an important physiological function for a Pol II regulatory factor (Gdown1) in the maintenance of normal liver cell transcription through constraints on cell cycle re-entry of quiescent hepatocytes., (© 2020 Jishage et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2020

10. Promoter-proximal pausing of RNA polymerase II: a nexus of gene regulation.

Author

Core L and Adelman K

Subjects

Animals, Enzyme Stability, Humans, Nucleosomes metabolism, RNA Polymerase II genetics, Transcription Elongation, Genetic, Gene Expression Regulation, Developmental, Promoter Regions, Genetic genetics, RNA Polymerase II metabolism

Abstract

Precise spatio-temporal control of gene activity is essential for organismal development, growth, and survival in a changing environment. Decisive steps in gene regulation involve the pausing of RNA polymerase II (Pol II) in early elongation, and the controlled release of paused polymerase into productive RNA synthesis. Here we describe the factors that enable pausing and the events that trigger Pol II release into the gene. We also discuss open questions in the field concerning the stability of paused Pol II, nucleosomes as obstacles to elongation, and potential roles of pausing in defining the precision and dynamics of gene expression., (© 2019 Core and Adelman; Published by Cold Spring Harbor Laboratory Press.)

Published

2019

11. Polymerase pausing induced by sequence-specific RNA-binding protein drives heterochromatin assembly.

Author

Parsa JY, Boudoukha S, Burke J, Homer C, and Madhani HD

Subjects

Microsatellite Repeats genetics, Nuclear Proteins genetics, RNA Interference, RNA Polymerase II metabolism, RNA-Binding Proteins genetics, Schizosaccharomyces pombe Proteins genetics, Chromatin Assembly and Disassembly genetics, Heterochromatin genetics, Heterochromatin metabolism, Nuclear Proteins metabolism, RNA Polymerase II genetics, RNA-Binding Proteins metabolism, Schizosaccharomyces enzymology, Schizosaccharomyces genetics, Schizosaccharomyces pombe Proteins metabolism

Abstract

In Schizosaccharomyces pombe , transcripts derived from the pericentromeric dg and dh repeats promote heterochromatin formation via RNAi as well as an RNAi-independent mechanism involving the RNA polymerase II (RNAPII)-associated RNA-binding protein Seb1 and RNA processing activities. We show that Seb1 promotes long-lived RNAPII pauses at pericentromeric repeat regions and that their presence correlates with the heterochromatin-triggering activities of the corresponding dg and dh DNA fragments. Globally increasing RNAPII stalling by other means induces the formation of novel large ectopic heterochromatin domains. Such ectopic heterochromatin occurs even in cells lacking RNAi. These results uncover Seb1-mediated polymerase stalling as a signal necessary for heterochromatin nucleation., (© 2018 Parsa et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2018

12. NDF, a nucleosome-destabilizing factor that facilitates transcription through nucleosomes.

Author

Fei J, Ishii H, Hoeksema MA, Meitinger F, Kassavetis GA, Glass CK, Ren B, and Kadonaga JT

Subjects

Amino Acid Motifs genetics, Animals, Breast Neoplasms genetics, Cell Nucleus, Chromatin metabolism, Drosophila Proteins genetics, Drosophila melanogaster genetics, Escherichia coli genetics, Gene Expression Regulation genetics, Histones metabolism, Humans, Mice, Nuclear Proteins genetics, Oxidoreductases genetics, Protein Transport, RNA Polymerase II genetics, RNA Polymerase II metabolism, Recombinant Proteins genetics, Recombinant Proteins metabolism, Drosophila Proteins metabolism, Nuclear Proteins metabolism, Nucleosomes metabolism, Oxidoreductases metabolism, Transcription, Genetic genetics

Abstract

Our understanding of transcription by RNA polymerase II (Pol II) is limited by our knowledge of the factors that mediate this critically important process. Here we describe the identification of NDF, a nucleosome-destabilizing factor that facilitates Pol II transcription in chromatin. NDF has a PWWP motif, interacts with nucleosomes near the dyad, destabilizes nucleosomes in an ATP-independent manner, and facilitates transcription by Pol II through nucleosomes in a purified and defined transcription system as well as in cell nuclei. Upon transcriptional induction, NDF is recruited to the transcribed regions of thousands of genes and colocalizes with a subset of H3K36me3-enriched regions. Notably, the recruitment of NDF to gene bodies is accompanied by an increase in the transcript levels of many of the NDF-enriched genes. In addition, the global loss of NDF results in a decrease in the RNA levels of many genes. In humans, NDF is present at high levels in all tested tissue types, is essential in stem cells, and is frequently overexpressed in breast cancer. These findings indicate that NDF is a nucleosome-destabilizing factor that is recruited to gene bodies during transcriptional activation and facilitates Pol II transcription through nucleosomes., (© 2018 Fei et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2018

13. Two distinct transcription termination modes dictated by promoters.

Author

Miki TS, Carl SH, and Großhans H

Subjects

Animals, Caenorhabditis elegans metabolism, Caenorhabditis elegans Proteins genetics, Exoribonucleases genetics, RNA Interference, RNA Polymerase II genetics, RNA, Messenger genetics, Caenorhabditis elegans genetics, Caenorhabditis elegans Proteins metabolism, Exoribonucleases metabolism, Promoter Regions, Genetic, RNA Polymerase II metabolism, Transcription Termination, Genetic physiology

Abstract

Transcription termination determines the ends of transcriptional units and thereby ensures the integrity of the transcriptome and faithful gene regulation. Studies in yeast and human cells have identified the exoribonuclease XRN2 as a key termination factor for protein-coding genes. Here we performed a genome-wide investigation of RNA polymerase II (Pol II) transcription termination in XRN2-deficient Caenorhabditis elegans and observed two distinct modes of termination. Although a subset of genes requires XRN2, termination of other genes appears both independent of, and refractory to, XRN2. XRN2 independence is not merely a consequence of failure to recruit XRN2, since XRN2 is present on-and promotes Pol II accumulation near the polyadenylation sites of-both gene classes. Unexpectedly, promoters instruct the choice of termination mode, but XRN2-independent termination additionally requires a compatible region downstream from the 3' end cleavage site. Hence, different termination mechanisms may work with different configurations of Pol II complexes dictated by promoters., (© 2017 Miki et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2017

14. The punctilious RNA polymerase II core promoter.

Author

Vo Ngoc L, Wang YL, Kassavetis GA, and Kadonaga JT

Subjects

Animals, Chromatin metabolism, DNA chemistry, Nucleotide Motifs genetics, Transcription Factors genetics, Transcriptional Activation genetics, Promoter Regions, Genetic genetics, RNA Polymerase II genetics

Abstract

The signals that direct the initiation of transcription ultimately converge at the core promoter, which is the gateway to transcription. Here we provide an overview of the RNA polymerase II core promoter in bilateria (bilaterally symmetric animals). The core promoter is diverse in terms of its composition and function yet is also punctilious, as it acts with strict rules and precision. We additionally describe an expanded view of the core promoter that comprises the classical DNA sequence motifs, sequence-specific DNA-binding transcription factors, chromatin signals, and DNA structure. This model may eventually lead to a more unified conceptual understanding of the core promoter., (© 2017 Vo ngoc et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2017

15. Transcriptional interference by RNA polymerase III affects expression of the Polr3e gene.

Author

Yeganeh M, Praz V, Cousin P, and Hernandez N

Subjects

Animals, Conserved Sequence genetics, DNA, Antisense genetics, Embryonic Stem Cells, Interspersed Repetitive Sequences genetics, Introns genetics, Mice, RNA Polymerase II genetics, RNA Polymerase III genetics, RNA, Messenger genetics, Sequence Deletion, Gene Expression Regulation genetics, RNA Polymerase III metabolism

Abstract

Overlapping gene arrangements can potentially contribute to gene expression regulation. A mammalian interspersed repeat (MIR) nested in antisense orientation within the first intron of the Polr3e gene, encoding an RNA polymerase III (Pol III) subunit, is conserved in mammals and highly occupied by Pol III. Using a fluorescence assay, CRISPR/Cas9-mediated deletion of the MIR in mouse embryonic stem cells, and chromatin immunoprecipitation assays, we show that the MIR affects Polr3e expression through transcriptional interference. Our study reveals a mechanism by which a Pol II gene can be regulated at the transcription elongation level by transcription of an embedded antisense Pol III gene., (© 2017 Yeganeh et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2017

16. Finding the start site: redefining the human initiator element.

Author

Kugel JF and Goodrich JA

Subjects

Base Sequence, Consensus Sequence, Humans, RNA Polymerase II genetics, TATA Box, Transcription, Genetic, Promoter Regions, Genetic, Transcription Initiation Site

Abstract

Transcription by RNA polymerase II (Pol II) is dictated in part by core promoter elements, which are DNA sequences flanking the transcription start site (TSS) that help direct the proper initiation of transcription. Taking advantage of recent advances in genome-wide sequencing approaches, Vo ngoc and colleagues (pp. 6-11) identified transcripts with focused sites of initiation and found that many were transcribed from promoters containing a new consensus sequence for the human initiator (Inr) core promoter element., (© 2017 Kugel and Goodrich; Published by Cold Spring Harbor Laboratory Press.)

Published

2017

17. Pre-mRNA splicing is facilitated by an optimal RNA polymerase II elongation rate.

Author

Fong N, Kim H, Zhou Y, Ji X, Qiu J, Saldi T, Diener K, Jones K, Fu XD, and Bentley DL

Subjects

Exons genetics, HEK293 Cells, Humans, Introns genetics, Mutation, RNA Polymerase II genetics, RNA Precursors genetics, RNA Polymerase II metabolism, RNA Precursors metabolism, RNA Splicing, Transcription Elongation, Genetic physiology

Abstract

Alternative splicing modulates expression of most human genes. The kinetic model of cotranscriptional splicing suggests that slow elongation expands and that fast elongation compresses the "window of opportunity" for recognition of upstream splice sites, thereby increasing or decreasing inclusion of alternative exons. We tested the model using RNA polymerase II mutants that change average elongation rates genome-wide. Slow and fast elongation affected constitutive and alternative splicing, frequently altering exon inclusion and intron retention in ways not predicted by the model. Cassette exons included by slow and excluded by fast elongation (type I) have weaker splice sites, shorter flanking introns, and distinct sequence motifs relative to "slow-excluded" and "fast-included" exons (type II). Many rate-sensitive exons are misspliced in tumors. Unexpectedly, slow and fast elongation often both increased or both decreased inclusion of a particular exon or retained intron. These results suggest that an optimal rate of transcriptional elongation is required for normal cotranscriptional pre-mRNA splicing., (© 2014 Fong et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2014

18. The SAGA coactivator complex acts on the whole transcribed genome and is required for RNA polymerase II transcription.

Author

Bonnet J, Wang CY, Baptista T, Vincent SD, Hsiao WC, Stierle M, Kao CF, Tora L, and Devys D

Subjects

Acetylation, Animals, Gene Expression Profiling, Genome, HEK293 Cells, HeLa Cells, Histones metabolism, Humans, Mice, Promoter Regions, Genetic, Protein Binding, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Trans-Activators genetics, Ubiquitination, Gene Expression Regulation, Gene Expression Regulation, Enzymologic genetics, RNA Polymerase II genetics, Saccharomyces cerevisiae Proteins metabolism, Trans-Activators metabolism

Abstract

The SAGA (Spt-Ada-Gcn5 acetyltransferase) coactivator complex contains distinct chromatin-modifying activities and is recruited by DNA-bound activators to regulate the expression of a subset of genes. Surprisingly, recent studies revealed little overlap between genome-wide SAGA-binding profiles and changes in gene expression upon depletion of subunits of the complex. As indicators of SAGA recruitment on chromatin, we monitored in yeast and human cells the genome-wide distribution of histone H3K9 acetylation and H2B ubiquitination, which are respectively deposited or removed by SAGA. Changes in these modifications after inactivation of the corresponding enzyme revealed that SAGA acetylates the promoters and deubiquitinates the transcribed region of all expressed genes. In agreement with this broad distribution, we show that SAGA plays a critical role for RNA polymerase II recruitment at all expressed genes. In addition, through quantification of newly synthesized RNA, we demonstrated that SAGA inactivation induced a strong decrease of mRNA synthesis at all tested genes. Analysis of the SAGA deubiquitination activity further revealed that SAGA acts on the whole transcribed genome in a very fast manner, indicating a highly dynamic association of the complex with chromatin. Thus, our study uncovers a new function for SAGA as a bone fide cofactor for all RNA polymerase II transcription., (© 2014 Bonnet et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2014

19. How an mRNA capping enzyme reads distinct RNA polymerase II and Spt5 CTD phosphorylation codes.

Author

Doamekpor SK, Sanchez AM, Schwer B, Shuman S, and Lima CD

Subjects

Genetic Code, Nucleotidyltransferases chemistry, Phosphorylation, Protein Structure, Quaternary, Protein Structure, Tertiary, Schizosaccharomyces genetics, Schizosaccharomyces metabolism, Threonine metabolism, Models, Molecular, Nucleotidyltransferases metabolism, RNA Polymerase II chemistry, RNA Polymerase II genetics, RNA Polymerase II metabolism, Schizosaccharomyces enzymology, Schizosaccharomyces pombe Proteins chemistry, Schizosaccharomyces pombe Proteins genetics, Schizosaccharomyces pombe Proteins metabolism, Transcriptional Elongation Factors chemistry, Transcriptional Elongation Factors genetics, Transcriptional Elongation Factors metabolism

Abstract

Interactions between RNA guanylyltransferase (GTase) and the C-terminal domain (CTD) repeats of RNA polymerase II (Pol2) and elongation factor Spt5 are thought to orchestrate cotranscriptional capping of nascent mRNAs. The crystal structure of a fission yeast GTase•Pol2 CTD complex reveals a unique docking site on the nucleotidyl transferase domain for an 8-amino-acid Pol2 CTD segment, S5PPSYSPTS5P, bracketed by two Ser5-PO4 marks. Analysis of GTase mutations that disrupt the Pol2 CTD interface shows that at least one of the two Ser5-PO4-binding sites is required for cell viability and that each site is important for cell growth at 37°C. Fission yeast GTase binds the Spt5 CTD at a separate docking site in the OB-fold domain that captures the Trp4 residue of the Spt5 nonapeptide repeat T(1)PAW(4)NSGSK. A disruptive mutation in the Spt5 CTD-binding site of GTase is synthetically lethal with mutations in the Pol2 CTD-binding site, signifying that the Spt5 and Pol2 CTDs cooperate to recruit capping enzyme in vivo. CTD phosphorylation has opposite effects on the interaction of GTase with Pol2 (Ser5-PO4 is required for binding) versus Spt5 (Thr1-PO4 inhibits binding). We propose that the state of Thr1 phosphorylation comprises a binary "Spt5 CTD code" that is read by capping enzyme independent of and parallel to its response to the state of the Pol2 CTD., (© 2014 Doamekpor et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2014

20. Kinetics of promoter Pol II on Hsp70 reveal stable pausing and key insights into its regulation.

Author

Buckley MS, Kwak H, Zipfel WR, and Lis JT

Subjects

Animals, Drosophila Proteins genetics, HSP70 Heat-Shock Proteins genetics, Kinetics, RNA Polymerase II genetics, Transgenes, Drosophila Proteins metabolism, Drosophila melanogaster enzymology, Drosophila melanogaster genetics, Gene Expression Regulation, HSP70 Heat-Shock Proteins metabolism, Promoter Regions, Genetic physiology, RNA Polymerase II metabolism

Abstract

The kinetics with which promoter-proximal paused RNA polymerase II (Pol II) undergoes premature termination versus productive elongation is central to understanding underlying mechanisms of metazoan transcription regulation. To assess the fate of Pol II quantitatively, we tracked photoactivatable GFP-tagged Pol II at uninduced Hsp70 on polytene chromosomes and showed that Pol II is stably paused with a half-life of 5 min. Biochemical analysis of short nascent RNA from Hsp70 reveals that this half-life is determined by two comparable rates of productive elongation and premature termination of paused Pol II. Importantly, heat shock dramatically increases elongating Pol II without decreasing termination, indicating that regulation acts at the step of paused Pol II entry to productive elongation.

Published

2014

21. Transcription initiation by human RNA polymerase II visualized at single-molecule resolution.

Author

Revyakin A, Zhang Z, Coleman RA, Li Y, Inouye C, Lucas JK, Park SR, Chu S, and Tjian R

Subjects

Humans, Microscopy, Fluorescence methods, Microscopy, Video methods, Mutation, Promoter Regions, Genetic, RNA Polymerase II genetics, RNA Polymerase II metabolism, Sp1 Transcription Factor chemistry, Sp1 Transcription Factor metabolism, Transcription Factor TFIID chemistry, Transcription Factor TFIID metabolism, Molecular Imaging methods, RNA Polymerase II chemistry, Transcription, Genetic

Abstract

Forty years of classical biochemical analysis have identified the molecular players involved in initiation of transcription by eukaryotic RNA polymerase II (Pol II) and largely assigned their functions. However, a dynamic picture of Pol II transcription initiation and an understanding of the mechanisms of its regulation have remained elusive due in part to inherent limitations of conventional ensemble biochemistry. Here we have begun to dissect promoter-specific transcription initiation directed by a reconstituted human Pol II system at single-molecule resolution using fluorescence video-microscopy. We detected several stochastic rounds of human Pol II transcription from individual DNA templates, observed attenuation of transcription by promoter mutations, observed enhancement of transcription by activator Sp1, and correlated the transcription signals with real-time interactions of holo-TFIID molecules at individual DNA templates. This integrated single-molecule methodology should be applicable to studying other complex biological processes.

Published

2012

22. Regulating the regulators: the pervasive effects of Pol II pausing on stimulus-responsive gene networks.

Author

Gilchrist DA, Fromm G, dos Santos G, Pham LN, McDaniel IE, Burkholder A, Fargo DC, and Adelman K

Subjects

Animals, Drosophila melanogaster immunology, Embryonic Stem Cells metabolism, Immunity genetics, Janus Kinases metabolism, Mice, RNA Polymerase II genetics, Signal Transduction, Transcription Factors genetics, Transcription Factors physiology, Drosophila melanogaster genetics, Drosophila melanogaster growth & development, Gene Expression Regulation, Developmental, Gene Regulatory Networks, RNA Polymerase II physiology, Transcriptional Activation

Abstract

The expression of many metazoan genes is regulated through controlled release of RNA polymerase II (Pol II) that has paused during early transcription elongation. Pausing is highly enriched at genes in stimulus-responsive pathways, where it has been proposed to poise downstream targets for rapid gene activation. However, whether this represents the major function of pausing in these pathways remains to be determined. To address this question, we analyzed pausing within several stimulus-responsive networks in Drosophila and discovered that paused Pol II is much more prevalent at genes encoding components and regulators of signal transduction cascades than at inducible downstream targets. Within immune-responsive pathways, we found that pausing maintains basal expression of critical network hubs, including the key NF-κB transcription factor that triggers gene activation. Accordingly, loss of pausing through knockdown of the pause-inducing factor NELF leads to broadly attenuated immune gene activation. Investigation of murine embryonic stem cells revealed that pausing is similarly widespread at genes encoding signaling components that regulate self-renewal, particularly within the MAPK/ERK pathway. We conclude that the role of pausing goes well beyond poising-inducible genes for activation and propose that the primary function of paused Pol II is to establish basal activity of signal-responsive networks.

Published

2012

23. DNA replication through hard-to-replicate sites, including both highly transcribed RNA Pol II and Pol III genes, requires the S. pombe Pfh1 helicase.

Author

Sabouri N, McDonald KR, Webb CJ, Cristea IM, and Zakian VA

Subjects

Cell Cycle Proteins genetics, Cell Cycle Proteins metabolism, DNA Helicases genetics, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, RNA, Transfer genetics, Schizosaccharomyces enzymology, Schizosaccharomyces pombe Proteins genetics, DNA Helicases metabolism, DNA Replication, Gene Expression Regulation, Enzymologic, Gene Expression Regulation, Fungal, RNA Polymerase II genetics, RNA Polymerase III genetics, Schizosaccharomyces genetics, Schizosaccharomyces pombe Proteins metabolism, Transcription, Genetic

Abstract

Replication forks encounter impediments as they move through the genome, including natural barriers due to stable protein complexes and highly transcribed genes. Unlike lesions generated by exogenous damage, natural barriers are encountered in every S phase. Like humans, Schizosaccharomyces pombe encodes a single Pif1 family DNA helicase, Pfh1. Here, we show that Pfh1 is required for efficient fork movement in the ribosomal DNA, the mating type locus, tRNA, 5S ribosomal RNA genes, and genes that are highly transcribed by RNA polymerase II. In addition, converged replication forks accumulated at all of these sites in the absence of Pfh1. The effects of Pfh1 on DNA replication are likely direct, as it had high binding to sites whose replication was impaired in its absence. Replication in the absence of Pfh1 resulted in DNA damage specifically at those sites that bound high levels of Pfh1 in wild-type cells and whose replication was slowed in its absence. Cells depleted of Pfh1 were inviable if they also lacked the human TIMELESS homolog Swi1, a replisome component that stabilizes stalled forks. Thus, Pfh1 promotes DNA replication and separation of converged replication forks and suppresses DNA damage at hard-to-replicate sites.

Published

2012

24. CDK12 is a transcription elongation-associated CTD kinase, the metazoan ortholog of yeast Ctk1.

Author

Bartkowiak B, Liu P, Phatnani HP, Fuda NJ, Cooper JJ, Price DH, Adelman K, Lis JT, and Greenleaf AL

Subjects

Animals, Blotting, Western, CDC2 Protein Kinase genetics, CDC2 Protein Kinase metabolism, Cell Line, Chromosome Mapping, Cyclin T genetics, Cyclin T metabolism, Cyclin-Dependent Kinase 9 genetics, Cyclin-Dependent Kinase 9 metabolism, Cyclin-Dependent Kinases genetics, Drosophila Proteins genetics, Drosophila melanogaster cytology, Drosophila melanogaster genetics, Drosophila melanogaster metabolism, Genetic Complementation Test, HeLa Cells, Humans, Microscopy, Fluorescence, Mutation, Phosphorylation, Protein Kinases genetics, RNA Interference, RNA Polymerase II genetics, RNA Polymerase II metabolism, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae growth & development, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Cyclin-Dependent Kinases metabolism, Drosophila Proteins metabolism, Protein Kinases metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

Drosophila contains one (dCDK12) and humans contain two (hCDK12 and hCDK13) proteins that are the closest evolutionary relatives of yeast Ctk1, the catalytic subunit of the major elongation-phase C-terminal repeat domain (CTD) kinase in Saccharomyces cerevisiae, CTDK-I. However, until now, neither CDK12 nor CDK13 has been demonstrated to be a bona fide CTD kinase. Using Drosophila, we demonstrate that dCDK12 (CG7597) is a transcription-associated CTD kinase, the ortholog of yCtk1. Fluorescence microscopy reveals that the distribution of dCDK12 on formaldehyde-fixed polytene chromosomes is virtually identical to that of hyperphosphorylated RNA polymerase II (RNAPII), but is distinct from that of P-TEFb (dCDK9 + dCyclin T). Chromatin immunoprecipitation (ChIP) experiments confirm that dCDK12 is present on the transcribed regions of active Drosophila genes. Compared with P-TEFb, dCDK12 amounts are lower at the 5' end and higher in the middle and at the 3' end of genes (both normalized to RNAPII). Appropriately, Drosophila dCDK12 purified from nuclear extracts manifests CTD kinase activity in vitro. Intriguingly, we find that cyclin K is associated with purified dCDK12, implicating it as the cyclin subunit of this CTD kinase. Most importantly, we demonstrate that RNAi knockdown of dCDK12 in S2 cells alters the phosphorylation state of the CTD, reducing its Ser2 phosphorylation levels. Similarly, in human HeLa cells, we show that hCDK13 purified from nuclear extracts displays CTD kinase activity in vitro, as anticipated. Also, we find that chimeric (yeast/human) versions of Ctk1 containing the kinase homology domains of hCDK12/13 (or hCDK9) are functional in yeast cells (and also in vitro); using this system, we show that a bur1(ts) mutant is rescued more efficiently by a hCDK9 chimera than by a hCDK13 chimera, suggesting the following orthology relationships: Bur1 ↔ CDK9 and Ctk1 ↔ CDK12/13. Finally, we show that siRNA knockdown of hCDK12 in HeLa cells results in alterations in the CTD phosphorylation state. Our findings demonstrate that metazoan CDK12 and CDK13 are CTD kinases, and that CDK12 is orthologous to yeast Ctk1.

Published

2010

25. Gene-specific repression of the p53 target gene PUMA via intragenic CTCF-Cohesin binding.

Author

Gomes NP and Espinosa JM

Subjects

Apoptosis genetics, CCCTC-Binding Factor, Chromatin genetics, HCT116 Cells, Humans, Peptide Elongation Factors metabolism, Promoter Regions, Genetic genetics, Protein Binding, RNA Polymerase II genetics, RNA Polymerase II metabolism, Transcription Factors, General metabolism, Tumor Suppressor Protein p53 metabolism, Cohesins, Apoptosis Regulatory Proteins metabolism, Cell Cycle Proteins metabolism, Chromosomal Proteins, Non-Histone metabolism, Gene Expression Regulation, Proto-Oncogene Proteins metabolism, Repressor Proteins metabolism

Abstract

The p53 transcriptional program orchestrates alternative responses to stress, including cell cycle arrest and apoptosis, but the mechanism of cell fate choice upon p53 activation is not fully understood. Here we report that PUMA (p53 up-regulated modulator of apoptosis), a key mediator of p53-dependent cell death, is regulated by a noncanonical, gene-specific mechanism. Using chromatin immunoprecipitation assays, we found that the first half of the PUMA locus (approximately 6 kb) is constitutively occupied by RNA polymerase II and general transcription factors regardless of p53 activity. Using various RNA analyses, we found that this region is constitutively transcribed to generate a long unprocessed RNA with no known coding capacity. This permissive intragenic domain is constrained by sharp chromatin boundaries, as illustrated by histone marks of active transcription (histone H3 Lys9 trimethylation [H3K4me3] and H3K9 acetylation [H3K9Ac]) that precipitously transition into repressive marks (H3K9me3). Interestingly, the insulator protein CTCF (CCCTC-binding factor) and the Cohesin complex occupy these intragenic chromatin boundaries. CTCF knockdown leads to increased basal expression of PUMA concomitant with a reduction in chromatin boundary signatures. Importantly, derepression of PUMA upon CTCF depletion occurs without p53 activation or activation of other p53 target genes. Therefore, CTCF plays a pivotal role in dampening the p53 apoptotic response by acting as a gene-specific repressor.

Published

2010

26. NRPD4, a protein related to the RPB4 subunit of RNA polymerase II, is a component of RNA polymerases IV and V and is required for RNA-directed DNA methylation.

Author

He XJ, Hsu YF, Pontes O, Zhu J, Lu J, Bressan RA, Pikaard C, Wang CS, and Zhu JK

Subjects

Amino Acid Sequence, Arabidopsis Proteins chemistry, Arabidopsis Proteins genetics, DNA Methylation genetics, DNA, Plant genetics, DNA, Plant metabolism, DNA-Directed RNA Polymerases chemistry, DNA-Directed RNA Polymerases genetics, Genes, Plant, Molecular Sequence Data, Mutation, Nuclear Proteins genetics, Nuclear Proteins metabolism, Phenotype, Plants, Genetically Modified, Protein Subunits, RNA Interference, RNA Polymerase II chemistry, RNA Polymerase II genetics, RNA, Plant genetics, RNA, Plant metabolism, RNA, Small Interfering genetics, RNA, Small Interfering metabolism, Sequence Homology, Amino Acid, Arabidopsis genetics, Arabidopsis metabolism, Arabidopsis Proteins metabolism, DNA Methylation physiology, DNA-Directed RNA Polymerases metabolism, RNA Polymerase II metabolism

Abstract

RNA-directed DNA methylation (RdDM) is an RNAi-based mechanism for establishing transcriptional gene silencing in plants. The plant-specific RNA polymerases IV and V are required for the generation of 24-nucleotide (nt) siRNAs and for guiding sequence-specific DNA methylation by the siRNAs, respectively. However, unlike the extensively studied multisubunit Pol II, our current knowledge about Pol IV and Pol V is restricted to only the two largest subunits NRPD1a/NRPD1 and NRPD1b/NRPE1 and the one second-largest subunit NRPD2a. It is unclear whether other subunits may be required for the functioning of Pol IV and Pol V in RdDM. From a genetic screen for second-site suppressors of the DNA demethylase mutant ros1, we identified a new component (referred to as RDM2) as well as seven known components (NRPD1, NRPE1, NRPD2a, AGO4, HEN1, DRD1, and HDA6) of the RdDM pathway. The differential effects of the mutations on two mechanistically distinct transcriptional silencing reporters suggest that RDM2, NRPD1, NRPE1, NRPD2a, HEN1, and DRD1 function only in the siRNA-dependent pathway of transcriptional silencing, whereas HDA6 and AGO4 have roles in both siRNA-dependent and -independent pathways of transcriptional silencing. In the rdm2 mutants, DNA methylation and siRNA accumulation were reduced substantially at loci previously identified as endogenous targets of Pol IV and Pol V, including 5S rDNA, MEA-ISR, AtSN1, AtGP1, and AtMU1. The amino acid sequence of RDM2 is similar to that of RPB4 subunit of Pol II, but we show evidence that RDM2 has diverged significantly from RPB4 and cannot function in Pol II. An association of RDM2 with both NRPD1 and NRPE1 was observed by coimmunoprecipitation and coimmunolocalization assays. Our results show that RDM2/NRPD4/NRPE4 is a new component of the RdDM pathway in Arabidopsis and that it functions as part of Pol IV and Pol V.

Published

2009

27. The Iws1:Spt6:CTD complex controls cotranscriptional mRNA biosynthesis and HYPB/Setd2-mediated histone H3K36 methylation.

Author

Yoh SM, Lucas JS, and Jones KA

Subjects

Acetylation, Animals, Cell Line, Cell Nucleus metabolism, Gene Knockdown Techniques, HIV-1 genetics, Humans, Jurkat Cells, Kruppel-Like Transcription Factors genetics, Methylation, Mice, Poly(A)-Binding Protein I genetics, Protein Binding, Proteins genetics, RNA Polymerase II genetics, RNA, Messenger metabolism, RNA-Binding Proteins, Transcription Factors, Gene Expression Regulation, Histone-Lysine N-Methyltransferase metabolism, Histones metabolism, Kruppel-Like Transcription Factors metabolism, Proteins metabolism, RNA Polymerase II metabolism, RNA, Messenger biosynthesis

Abstract

Many steps in gene expression and mRNA biosynthesis are coupled to transcription elongation and organized through the C-terminal domain (CTD) of the large subunit of RNA polymerase II (RNAPII). We showed recently that Spt6, a transcription elongation factor and histone H3 chaperone, binds to the Ser2P CTD and recruits Iws1 and the REF1/Aly mRNA export adaptor to facilitate mRNA export. Here we show that Iws1 also recruits the HYPB/Setd2 histone methyltransferase to the RNAPII elongation complex and is required for H3K36 trimethylation (H3K36me3) across the transcribed region of the c-Myc, HIV-1, and PABPC1 genes in vivo. Interestingly, knockdown of either Iws1 or HYPB/Setd2 also enhanced H3K27me3 at the 5' end of the PABPC1 gene, and depletion of Iws1, but not HYPB/Setd2, increased histone acetylation across the coding regions at the HIV-1 and PABPC1 genes in vivo. Knockdown of HYPB/Setd2, like Iws1, induced bulk HeLa poly(A)+ mRNAs to accumulate in the nucleus. In vitro, recombinant Spt6 binds selectively to a stretch of uninterrupted consensus repeats located in the N-terminal half of the CTD and recruits Iws1. Thus Iws1 connects two distinct CTD-binding proteins, Spt6 and HYPB/Setd2, in a megacomplex that affects mRNA export as well as the histone modification state of active genes.

Published

2008

28. Caudal, a key developmental regulator, is a DPE-specific transcriptional factor.

Author

Juven-Gershon T, Hsu JY, and Kadonaga JT

Subjects

Animals, Base Sequence, Drosophila Proteins genetics, Drosophila melanogaster genetics, Drosophila melanogaster metabolism, Enhancer Elements, Genetic, Homeodomain Proteins genetics, Molecular Sequence Data, RNA Polymerase II genetics, RNA Polymerase II metabolism, Sequence Homology, Nucleic Acid, TATA Box genetics, Transcription Factor TFIID genetics, Transcription Factors genetics, Transfection, Drosophila Proteins metabolism, Gene Expression Regulation, Homeodomain Proteins metabolism, Promoter Regions, Genetic genetics, Regulatory Elements, Transcriptional genetics, Transcription Factor TFIID metabolism, Transcription Factors metabolism, Transcription, Genetic

Abstract

The regulation of gene transcription is critical for the proper development and growth of an organism. The transcription of protein-coding genes initiates at the RNA polymerase II core promoter, which is a diverse module that can be controlled by many different elements such as the TATA box and downstream core promoter element (DPE). To understand the basis for core promoter diversity, we explored potential biological functions of the DPE. We found that nearly all of the Drosophila homeotic (Hox) gene promoters, which lack TATA-box elements, contain functionally important DPE motifs that are conserved from Drosophila melanogaster to Drosophila virilis. We then discovered that Caudal, a sequence-specific transcription factor and key regulator of the Hox gene network, activates transcription with a distinct preference for the DPE relative to the TATA box. The specificity of Caudal activation for the DPE is particularly striking when a BRE(u) core promoter motif is associated with the TATA box. These findings show that Caudal is a DPE-specific activator and exemplify how core promoter diversity can be used to establish complex regulatory networks.

Published

2008

29. Histone H3 K36 methylation is mediated by a trans-histone methylation pathway involving an interaction between Set2 and histone H4.

Author

Du HN, Fingerman IM, and Briggs SD

Subjects

Antimetabolites pharmacology, Blotting, Western, Chromatin metabolism, Chromatin Immunoprecipitation, Immunoblotting, Immunoprecipitation, Lysine chemistry, Lysine genetics, Lysine metabolism, Methyltransferases genetics, Mutation genetics, Nucleosomes metabolism, Phosphorylation, Protein Kinases metabolism, Protein Processing, Post-Translational, RNA Polymerase II genetics, RNA Polymerase II metabolism, Saccharomyces cerevisiae Proteins genetics, Transcription, Genetic, Uracil analogs & derivatives, Uracil pharmacology, Gene Expression Regulation, Fungal, Histones genetics, Histones metabolism, Methylation, Methyltransferases metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

Set2-mediated H3 K36 methylation is an important histone modification on chromatin during transcription elongation. Although Set2 associates with the phosphorylated C-terminal domain (CTD) of RNA polymerase II (RNAPII), the mechanism of Set2 binding to chromatin and subsequent exertion of its methyltransferase activity is relatively uncharacterized. We identified a critical lysine residue in histone H4 that is needed for interaction with Set2 and proper H3 K36 di- and trimethylation. We also determined that the N terminus of Set2 contains a histone H4 interaction motif that allows Set2 to bind histone H4 and nucleosomes. A Set2 mutant lacking the histone H4 interaction motif is able to bind to the phosphorylated CTD of RNAPII and associate with gene-specific loci but is defective for H3 K36 di- and trimethylation. In addition, this Set2 mutant shows increased H4 acetylation and resistance to 6-Azauracil. Overall, our study defines a new interaction between Set2 and histone H4 that mediates trans-histone regulation of H3 K36 methylation, which is needed for the preventative maintenance and integrity of the genome.

Published

2008

30. Sus1 is recruited to coding regions and functions during transcription elongation in association with SAGA and TREX2.

Author

Pascual-García P, Govind CK, Queralt E, Cuenca-Bono B, Llopis A, Chavez S, Hinnebusch AG, and Rodríguez-Navarro S

Subjects

Blotting, Western, Chromatin Immunoprecipitation, Gene Expression Regulation, Fungal, Immunoprecipitation, Methylation, Nuclear Proteins genetics, Phosphoproteins genetics, Phosphorylation, RNA Polymerase II genetics, RNA Polymerase II metabolism, RNA Transport, RNA, Messenger genetics, RNA-Binding Proteins genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Trans-Activators genetics, Nuclear Proteins metabolism, Open Reading Frames physiology, Phosphoproteins metabolism, RNA, Messenger metabolism, RNA-Binding Proteins metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins metabolism, Trans-Activators metabolism, Transcription, Genetic

Abstract

Gene transcription, RNA biogenesis, and mRNA transport constitute a complicated process essential for all eukaryotic cells. The transcription/export factor Sus1 plays a key role in coupling transcription activation with mRNA export, and it resides in both the SAGA and TREX2 complexes. Moreover, Sus1 is responsible for GAL1 gene gating at the nuclear periphery, which is important for its transcriptional status. Here, we show that Sus1 is required during transcription elongation and is associated with the elongating form of RNA Polymerase II (RNAP II) phosphorylated on Ser5 and Ser2 of the C-terminal domain (CTD). In addition, Sus1 copurifies with the essential mRNA export factors Yra1 and Mex67, which bind to the mRNA cotranscriptionally. Consistently, ChIP analysis reveals that Sus1 is present at coding regions dependent on transcription in a manner stimulated by Kin28-dependent CTD phosphorylation. Strikingly, eliminating the TREX2 component Sac3 or the SAGA subunit Ubp8 partially impairs Sus1 targeting to coding sequences and upstream activating sequences (UAS). We found, unexpectedly, that Sgf73 is necessary for association of Sus1 with both SAGA and TREX2, and that its absence dramatically reduces Sus1 occupancy of UAS and ORF sequences. Our results reveal that Sus1 plays a key role in coordinating gene transcription and mRNA export by working at the interface between the SAGA and TREX2 complexes during transcription elongation.

Published

2008

31. TBP, Mot1, and NC2 establish a regulatory circuit that controls DPE-dependent versus TATA-dependent transcription.

Author

Hsu JY, Juven-Gershon T, Marr MT 2nd, Wright KJ, Tjian R, and Kadonaga JT

Subjects

Animals, Cells, Cultured, Drosophila genetics, Drosophila Proteins genetics, Enhancer Elements, Genetic, Gene Expression Regulation, Promoter Regions, Genetic, RNA Polymerase II genetics, Transcription Factors genetics, Drosophila physiology, Drosophila Proteins physiology, TATA Box, TATA-Box Binding Protein genetics, Transcription Factors physiology, Transcription, Genetic

Abstract

The RNA polymerase II core promoter is a structurally and functionally diverse transcriptional module. RNAi depletion and overexpression experiments revealed a genetic circuit that controls the balance of transcription from two core promoter motifs, the TATA box and the downstream core promoter element (DPE). In this circuit, TBP activates TATA-dependent transcription and represses DPE-dependent transcription, whereas Mot1 and NC2 block TBP function and thus repress TATA-dependent transcription and activate DPE-dependent transcription. This regulatory circuit is likely to be one means by which biological networks can transmit transcriptional signals, such as those from DPE-specific and TATA-specific enhancers, via distinct pathways.

Published

2008

32. NELF-mediated stalling of Pol II can enhance gene expression by blocking promoter-proximal nucleosome assembly.

Author

Gilchrist DA, Nechaev S, Lee C, Ghosh SK, Collins JB, Li L, Gilmour DS, and Adelman K

Subjects

Animals, Chromatin Immunoprecipitation, DNA Footprinting, Drosophila Proteins genetics, Drosophila melanogaster genetics, Gene Expression Profiling, Genes, Dominant, Luciferases metabolism, Oligonucleotide Array Sequence Analysis, Polymerase Chain Reaction, RNA Polymerase II genetics, Transcription Factors antagonists & inhibitors, Transcription Factors genetics, Chromatin Assembly and Disassembly physiology, Drosophila Proteins metabolism, Drosophila melanogaster metabolism, Gene Expression Regulation, Promoter Regions, Genetic genetics, RNA Polymerase II metabolism, Transcription Factors metabolism

Abstract

The Negative Elongation Factor (NELF) is a transcription regulatory complex that induces stalling of RNA polymerase II (Pol II) during early transcription elongation and represses expression of several genes studied to date, including Drosophila Hsp70, mammalian proto-oncogene junB, and HIV RNA. To determine the full spectrum of NELF target genes in Drosophila, we performed a microarray analysis of S2 cells depleted of NELF and discovered that NELF RNAi affects many rapidly inducible genes involved in cellular responses to stimuli. Surprisingly, only one-third of NELF target genes were, like Hsp70, up-regulated by NELF-depletion, whereas the majority of target genes showed decreased expression levels upon NELF RNAi. Our data reveal that the presence of stalled Pol II at this latter group of genes enhances gene expression by maintaining a permissive chromatin architecture around the promoter-proximal region, and that loss of Pol II stalling at these promoters is accompanied by a significant increase in nucleosome occupancy and a decrease in histone H3 Lys 4 trimethylation. These findings identify a novel, positive role for stalled Pol II in regulating gene expression and suggest that there is a dynamic interplay between stalled Pol II and chromatin structure.

Published

2008

33. Synchronicity: policing multiple aspects of gene expression by Ctk1.

Author

Hampsey M and Kinzy TG

Subjects

Protein Kinases genetics, RNA Polymerase II genetics, RNA, Messenger genetics, Saccharomyces cerevisiae Proteins genetics, Transcription, Genetic, Protein Biosynthesis, Protein Kinases metabolism, RNA Polymerase II metabolism, RNA, Messenger metabolism, Saccharomyces cerevisiae Proteins metabolism

Published

2007

34. The RNA polymerase II CTD kinase Ctk1 functions in translation elongation.

Author

Röther S and Strässer K

Subjects

Codon, Cyclin-Dependent Kinase 9 metabolism, Gene Expression Regulation, Fungal, Models, Molecular, Phosphorylation, Protein Kinases genetics, RNA Polymerase II genetics, Ribosomes metabolism, Saccharomyces cerevisiae Proteins genetics, Transcription, Genetic, Polyribosomes metabolism, Protein Biosynthesis, Protein Kinases metabolism, RNA Polymerase II metabolism, RNA, Messenger metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

Translation is a highly complex process that is regulated by a multitude of factors. Here, we show that the conserved kinase Ctk1 functions in translation by enhancing decoding fidelity. Ctk1 associates with translating ribosomes in vivo and is needed for efficient translation. Ctk1 phosphorylates Rps2, a protein of the small ribosomal subunit, on Ser 238. Importantly, Ctk1-depleted as well as rps2-S238A mutant cells show a defect in translation elongation through an increase in the frequency of miscoding. The role of Ctk1 in translation may be conserved as the mammalian homolog of Ctk1, CDK9, also associates with polysomes. Since Ctk1 interacts with the TREX (transcription and mRNA export) complex, which couples transcription to mRNA export, Ctk1/CDK9 might bind to correctly processed mRNPs during transcription and accompany the mRNP to the ribosomes in the cytoplasm, where Ctk1 enhances efficient and accurate translation of the mRNA.

Published

2007

35. Nucleosome displacement in transcription.

Author

Workman JL

Subjects

Animals, Humans, RNA Polymerase II genetics, RNA, Messenger metabolism, Transcriptional Elongation Factors genetics, Nucleosomes physiology, Transcription, Genetic

Abstract

Recent reports reinforce the notion that nucleosomes are highly dynamic in response to the process of transcription. Nucleosomes are displaced at promoters during gene activation in a process that involves histone modification, ATP-dependent nucleosome remodeling complexes, histone chaperones and perhaps histone variants. During transcription elongation nucleosomes are acetylated and transferred behind RNA polymerase II where they are required to suppress spurious transcription initiation within the body of the gene. It is becoming increasingly clear that the eukaryotic transcriptional machinery is adapted to exploit the presence of nucleosomes in very sophisticated ways.

Published

2006

36. Functional coupling of RNAP II transcription to spliceosome assembly.

Author

Das R, Dufu K, Romney B, Feldt M, Elenko M, and Reed R

Subjects

DNA-Directed RNA Polymerases genetics, DNA-Directed RNA Polymerases metabolism, HeLa Cells, Humans, RNA Polymerase II genetics, RNA Precursors genetics, Ribonucleoproteins genetics, Ribonucleoproteins metabolism, Viral Proteins genetics, Viral Proteins metabolism, RNA Polymerase II metabolism, RNA Precursors metabolism, RNA Splicing, Spliceosomes physiology, Transcription, Genetic

Abstract

The pathway of gene expression in higher eukaryotes involves a highly complex network of physical and functional interactions among the different machines involved in each step of the pathway. Here we established an efficient in vitro system to determine how RNA polymerase II (RNAP II) transcription is functionally coupled to pre-mRNA splicing. Strikingly, our data show that nascent pre-messenger RNA (pre-mRNA) synthesized by RNAP II is immediately and quantitatively directed into the spliceosome assembly pathway. In contrast, nascent pre-mRNA synthesized by T7 RNA polymerase is quantitatively assembled into the nonspecific H complex, which consists of heterogeneous nuclear ribonucleoprotein (hnRNP) proteins and is inhibitory for spliceosome assembly. Consequently, RNAP II transcription results in a dramatic increase in both the kinetics of splicing and overall yield of spliced mRNA relative to that observed for T7 transcription. We conclude that RNAP II mediates the functional coupling of transcription to splicing by directing the nascent pre-mRNA into spliceosome assembly, thereby bypassing interaction of the pre-mRNA with the inhibitory hnRNP proteins.

Published

2006

37. RNA Pol II subunit Rpb7 promotes centromeric transcription and RNAi-directed chromatin silencing.

Author

Djupedal I, Portoso M, Spåhr H, Bonilla C, Gustafsson CM, Allshire RC, and Ekwall K

Subjects

Centromere genetics, Centromere metabolism, Chromatin genetics, Gene Expression Regulation, Fungal physiology, Promoter Regions, Genetic physiology, RNA Polymerase II genetics, RNA Processing, Post-Transcriptional physiology, RNA, Small Interfering genetics, Ribonuclease III metabolism, Schizosaccharomyces pombe Proteins genetics, Transcription, Genetic physiology, Chromatin metabolism, RNA Interference physiology, RNA Polymerase II metabolism, RNA, Small Interfering metabolism, Schizosaccharomyces physiology, Schizosaccharomyces pombe Proteins metabolism

Abstract

Fission yeast centromeric repeats are transcribed into small interfering RNA (siRNA) precursors (pre-siRNAs), which are processed by Dicer to direct heterochromatin formation. Recently, Rpb1 and Rpb2 subunits of RNA polymerase II (RNA Pol II) were shown to mediate RNA interference (RNAi)-directed chromatin modification but did not affect pre-siRNA levels. Here we show that another Pol II subunit, Rpb7 has a specific role in pre-siRNA transcription. We define a centromeric pre-siRNA promoter from which initiation is exquisitely sensitive to the rpb7-G150D mutation. In contrast to other Pol II subunits, Rpb7 promotes pre-siRNA transcription required for RNAi-directed chromatin silencing.

Published

2005

38. A structural perspective of CTD function.

Author

Meinhart A, Kamenski T, Hoeppner S, Baumli S, and Cramer P

Subjects

Amino Acid Sequence, Binding Sites, Carrier Proteins metabolism, Models, Molecular, Molecular Sequence Data, Molecular Structure, Phosphoprotein Phosphatases chemistry, Phosphoprotein Phosphatases metabolism, Phosphorylation, Protein Kinases chemistry, Protein Kinases metabolism, Protein Structure, Tertiary, RNA Polymerase II genetics, RNA Polymerase II metabolism, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins metabolism, mRNA Cleavage and Polyadenylation Factors, RNA Polymerase II chemistry

Abstract

The C-terminal domain (CTD) of RNA polymerase II (Pol II) integrates nuclear events by binding proteins involved in mRNA biogenesis. CTD-binding proteins recognize a specific CTD phosphorylation pattern, which changes during the transcription cycle, due to the action of CTD-modifying enzymes. Structural and functional studies of CTD-binding and -modifying proteins now reveal some of the mechanisms underlying CTD function. Proteins recognize CTD phosphorylation patterns either directly, by contacting phosphorylated residues, or indirectly, without contact to the phosphate. The catalytic mechanisms of CTD kinases and phosphatases are known, but the basis for CTD specificity of these enzymes remains to be understood.

Published

2005

39. The MTE, a new core promoter element for transcription by RNA polymerase II.

Author

Lim CY, Santoso B, Boulay T, Dong E, Ohler U, and Kadonaga JT

Subjects

Base Sequence, Conserved Sequence, HeLa Cells, Humans, RNA Polymerase II genetics, TATA Box, Transcription Factor TFIID genetics, Transcription Factor TFIID metabolism, Transcription Factors genetics, Transcription Factors metabolism, Promoter Regions, Genetic, RNA Polymerase II metabolism, Transcription, Genetic

Abstract

The core promoter is the ultimate target of the vast network of regulatory factors that contribute to the initiation of transcription by RNA polymerase II. Here we describe the MTE (motif ten element), a new core promoter element that appears to be conserved from Drosophila to humans. The MTE promotes transcription by RNA polymerase II when it is located precisely at positions +18 to +27 relative to A(+1) in the initiator (Inr) element. MTE sequences from +18 to +22 relative to A(+1) are important for basal transcription, and a region from +18 to +27 is sufficient to confer MTE activity to heterologous core promoters. The MTE requires the Inr, but functions independently of the TATA-box and DPE. Notably, the loss of transcriptional activity upon mutation of a TATA-box or DPE can be compensated by the addition of an MTE. In addition, the MTE exhibits strong synergism with the TATA-box as well as the DPE. These findings indicate that the MTE is a novel downstream core promoter element that is important for transcription by RNA polymerase II.

Published

2004

40. Pin1 modulates the structure and function of human RNA polymerase II.

Author

Xu YX, Hirose Y, Zhou XZ, Lu KP, and Manley JL

Subjects

Animals, Cyclin B metabolism, Fibroblasts metabolism, HeLa Cells, Humans, Mice, Mitosis genetics, NIH 3T3 Cells, NIMA-Interacting Peptidylprolyl Isomerase, Phosphorylation, Precipitin Tests, RNA Polymerase II chemistry, RNA Polymerase II genetics, RNA Precursors genetics, RNA Precursors metabolism, Spliceosomes, Transcription, Genetic, Peptidylprolyl Isomerase physiology, Phosphoprotein Phosphatases metabolism, RNA Polymerase II metabolism, RNA Splicing

Abstract

The C-terminal domain of the RNA polymerase (RNAP) II largest subunit (CTD) plays critical roles both in transcription of mRNA precursors and in the processing reactions needed to form mature mRNAs. The CTD undergoes dynamic changes in phosphorylation during the transcription cycle, and this plays a significant role in coordinating its multiple activities. But how these changes themselves are regulated is not well understood. Here we show that the peptidyl-prolyl isomerase Pin1 influences the phosphorylation status of the CTD in vitro by inhibiting the CTD phosphatase FCP1 and stimulating CTD phosphorylation by cdc2/cyclin B. This is reflected in vivo by accumulation of hypophosphorylated RNAP II in pin1-/- cells, and of a novel hyper-hyperphosphorylated form in cells induced to overexpress Pin1. This hyper-hyperphosphorylated form of RNAP II also accumulates in M-phase cells, in a Pin1-dependent manner, and associates specifically with Pin1. Functionally, we find that Pin1 overexpression specifically inhibits ongoing transcription of mRNA precursors in vivo and both transcription and RNAP II-stimulated pre-mRNA splicing in cell extracts. Pin1 thus plays a significant role in regulating RNAP II CTD structure and function.

Published

2003

41. Generation of Ski-knockdown mice by expressing a long double-strand RNA from an RNA polymerase II promoter.

Author

Shinagawa T and Ishii S

Subjects

5' Untranslated Regions genetics, Abnormalities, Multiple embryology, Abnormalities, Multiple genetics, Animals, Base Sequence, Cells, Cultured, Crosses, Genetic, Cytoplasm metabolism, DNA-Binding Proteins deficiency, DNA-Binding Proteins metabolism, Embryo, Mammalian, Female, Fibroblasts cytology, Fibroblasts enzymology, Genetic Vectors, Luciferases genetics, Luciferases metabolism, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Mice, Transgenic, Molecular Sequence Data, Proto-Oncogene Proteins deficiency, Proto-Oncogene Proteins metabolism, RNA Polymerase II metabolism, Recombinant Proteins metabolism, Repressor Proteins genetics, Repressor Proteins metabolism, Reverse Transcriptase Polymerase Chain Reaction, Transcription, Genetic, Transfection, DNA-Binding Proteins genetics, Promoter Regions, Genetic genetics, Proto-Oncogene Proteins genetics, RNA Polymerase II genetics, RNA, Double-Stranded genetics

Abstract

We have developed a new vector, named pDECAP, to express long double-strand RNA (ds-RNA) from an RNA polymerase II (Pol II) promoter. Because the transcripts from pDECAP lack both the 5'-cap structure and the 3'-poly(A) tail that facilitate ds-RNA export to the cytoplasm, long ds-RNA from pDECAP does not induce the interferon response. Transgenic mice embryos expressing long ds-RNA for the transcriptional corepressor Ski from this vector exhibited phenotypes that were remarkably similar to those of Ski-deficient embryos, including defects of neural tube closure and eye formation. Thus, this vector provides a new tool to efficiently generate tissue-specific knockdown mice for studying gene function in whole animal systems.

Published

2003

42. NELF and DSIF cause promoter proximal pausing on the hsp70 promoter in Drosophila.

Author

Wu CH, Yamaguchi Y, Benjamin LR, Horvat-Gordon M, Washinsky J, Enerly E, Larsson J, Lambertsson A, Handa H, and Gilmour D

Subjects

Animals, Base Sequence, Cell Nucleus genetics, Cell Nucleus physiology, Chromosome Mapping, Cloning, Molecular, DNA Primers, DNA-Directed RNA Polymerases genetics, Drosophila Proteins metabolism, Drosophila melanogaster embryology, Embryo, Nonmammalian physiology, Gene Deletion, Heat-Shock Proteins genetics, Humans, Nuclear Proteins metabolism, Protein Subunits genetics, RNA Polymerase II genetics, RNA Polymerase II metabolism, RNA-Binding Proteins metabolism, Salivary Glands enzymology, Salivary Glands physiology, Transcription Factors metabolism, Transcriptional Elongation Factors, Drosophila Proteins genetics, Drosophila melanogaster genetics, HSP70 Heat-Shock Proteins genetics, Nuclear Proteins genetics, RNA-Binding Proteins genetics, Repressor Proteins, Transcription Factors genetics

Abstract

NELF and DSIF collaborate to inhibit elongation by RNA polymerase IIa in extracts from human cells. A multifaceted approach was taken to investigate the potential role of these factors in promoter proximal pausing on the hsp70 gene in Drosophila. Immunodepletion of DSIF from a Drosophila nuclear extract reduced the level of polymerase that paused in the promoter proximal region of hsp70. Depletion of one NELF subunit in salivary glands using RNA interference also reduced the level of paused polymerase. In vivo protein-DNA cross-linking showed that NELF and DSIF associate with the promoter region before heat shock. Immunofluorescence analysis of polytene chromosomes corroborated the cross-linking result and showed that NELF, DSIF, and RNA polymerase IIa colocalize at the hsp70 genes, small heat shock genes, and many other chromosomal locations. Finally, following heat shock induction, DSIF and polymerase but not NELF were strongly recruited to chromosomal puffs harboring the hsp70 genes. We propose that NELF and DSIF cause polymerase to pause in the promoter proximal region of hsp70. The transcriptional activator, HSF, might cause NELF to dissociate from the elongation complex. DSIF continues to associate with the elongation complex and could serve a positive role in elongation.

Published

2003

43. Phosphorylation of RNA polymerase II CTD regulates H3 methylation in yeast.

Author

Xiao T, Hall H, Kizer KO, Shibata Y, Hall MC, Borchers CH, and Strahl BD

Subjects

DNA Methylation, Gene Expression Regulation, Fungal physiology, Methyltransferases metabolism, Peptides metabolism, Phosphorylation, Protein Structure, Tertiary, RNA Polymerase II metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Histones metabolism, Protein Kinases, RNA Polymerase II genetics

Abstract

Histone methylation is now realized to be a pivotal regulator of gene transcription. Although recent studies have shed light on a trans-histone regulatory pathway that controls H3 Lys 4 and H3 Lys 79 methylation in Saccharomyces cerevisiae, the regulatory pathway that affects Set2-mediated H3 Lys 36 methylation is unknown. To determine the functions of Set2, and identify factors that regulate its site of methylation, we genomically tagged Set2 and identified its associated proteins. Here, we show that Set2 is associated with Rbp1 and Rbp2, the two largest subunits of RNA polymerase II (RNA pol II). Moreover, we find that this association is specific for the interaction of Set2 with the hyperphosphorylated form of RNA pol II. We further show that deletion of the RNA pol II C-terminal domain (CTD) kinase Ctk1, or partial deletion of the CTD, results in a selective abolishment of H3 Lys 36 methylation, implying a pathway of Set2 recruitment to chromatin and a role for H3 Lys 36 methylation in transcription elongation. In support, chromatin immunoprecipitation assays demonstrate the presence of Set2 methylation in the coding regions, as well as promoters, of genes regulated by Ctk1 or Set2. These data document a new link between histone methylation and the transcription apparatus and uncover a regulatory pathway that is selective for H3 Lys 36 methylation.

Published

2003

44. SWI/SNF-dependent chromatin remodeling of RNR3 requires TAF(II)s and the general transcription machinery.

Author

Sharma VM, Li B, and Reese JC

Subjects

Acetylation, Chromatin genetics, Cyclin-Dependent Kinases genetics, Cyclin-Dependent Kinases metabolism, DNA-Binding Proteins genetics, Fungal Proteins genetics, Fungal Proteins metabolism, Histones metabolism, Mediator Complex, Mutation, Nuclear Proteins genetics, Nuclear Proteins metabolism, Nucleosomes metabolism, Promoter Regions, Genetic, Protein Kinases genetics, RNA Polymerase II genetics, RNA Polymerase II metabolism, Ribonucleoprotein, U1 Small Nuclear genetics, Ribonucleotide Reductases genetics, Saccharomyces cerevisiae Proteins genetics, TATA-Binding Protein Associated Factors genetics, Transcription Factor TFIID genetics, Transcription Factors genetics, Transcription Factors metabolism, Yeasts metabolism, Chromatin metabolism, DNA-Binding Proteins metabolism, Drosophila Proteins, Protein Kinases metabolism, RNA-Binding Proteins, Ribonucleoprotein, U1 Small Nuclear metabolism, Ribonucleotide Reductases metabolism, Saccharomyces cerevisiae Proteins metabolism, TATA-Binding Protein Associated Factors metabolism, Transcription Factor TFIID metabolism, Transcription, Genetic, Yeasts genetics

Abstract

Gene expression requires the recruitment of chromatin remodeling activities and general transcription factors (GTFs) to promoters. Whereas the role of activators in recruiting chromatin remodeling activities has been clearly demonstrated, the contributions of the transcription machinery have not been firmly established. Here we demonstrate that the remodeling of the RNR3 promoter requires a number of GTFs, mediator and RNA polymerase II. We also show that remodeling is dependent upon the SWI/SNF complex, and that TFIID and RNA polymerase II are required for its recruitment to the promoter. In contrast, Gcn5p-dependent histone acetylation occurs independently of TFIID and RNA polymerase II function, and we provide evidence that acetylation increases the extent of nucleosome remodeling, but is not required for SWI/SNF recruitment. Thus, the general transcription machinery can contribute to nucleosome remodeling by mediating the association of SWI/SNF with promoters, thereby revealing a novel pathway for the recruitment of chromatin remodeling activities.

Published

2003

45. Spt5 and spt6 are associated with active transcription and have characteristics of general elongation factors in D. melanogaster.

Author

Kaplan CD, Morris JR, Wu C, and Winston F

Subjects

Animals, Chromosomes metabolism, Cyclin T, Cyclins metabolism, Drosophila Proteins, Drosophila melanogaster embryology, Embryo, Nonmammalian, Fungal Proteins metabolism, Gene Expression Regulation, Developmental, Glue Proteins, Drosophila genetics, Glue Proteins, Drosophila metabolism, Heat-Shock Response, Histone Chaperones, Molecular Sequence Data, Peptide Elongation Factors genetics, Peptide Elongation Factors metabolism, RNA Polymerase II genetics, RNA Polymerase II metabolism, Sequence Analysis, Transcription, Genetic, Chromosomal Proteins, Non-Histone, Drosophila melanogaster genetics, Fungal Proteins genetics, Insect Proteins genetics, Insect Proteins metabolism, Nuclear Proteins genetics, Nuclear Proteins metabolism, Saccharomyces cerevisiae Proteins, Transcriptional Elongation Factors

Abstract

The Spt4, Spt5, and Spt6 proteins are conserved throughout eukaryotes and are believed to play critical and related roles in transcription. They have a positive role in transcription elongation in Saccharomyces cerevisiae and in the activation of transcription by the HIV Tat protein in human cells. In contrast, a complex of Spt4 and Spt5 is required in vitro for the inhibition of RNA polymerase II (Pol II) elongation by the drug DRB, suggesting also a negative role in vivo. To learn more about the function of the Spt4/Spt5 complex and Spt6 in vivo, we have identified Drosophila homologs of Spt5 and Spt6 and characterized their localization on Drosophila polytene chromosomes. We find that Spt5 and Spt6 localize extensively with the phosphorylated, actively elongating form of Pol II, to transcriptionally active sites during salivary gland development and upon heat shock. Furthermore, Spt5 and Spt6 do not colocalize widely with the unphosphorylated, nonelongating form of Pol II. These results strongly suggest that Spt5 and Spt6 play closely related roles associated with active transcription in vivo.

Published

2000

46. Activation mutants in yeast RNA polymerase II subunit RPB3 provide evidence for a structurally conserved surface required for activation in eukaryotes and bacteria.

Author

Tan Q, Linask KL, Ebright RH, and Woychik NA

Subjects

Amino Acid Sequence, Blotting, Northern, Conserved Sequence, Crystallography, X-Ray, Models, Molecular, Molecular Sequence Data, Mutation, Missense, Protein Structure, Secondary, RNA Polymerase II chemistry, RNA Polymerase II genetics, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae genetics, Sequence Homology, Amino Acid, Bacteria enzymology, Gene Expression Regulation, Promoter Regions, Genetic, RNA Polymerase II metabolism, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae Proteins, Transcription, Genetic

Abstract

We have identified a mutant in RPB3, the third-largest subunit of yeast RNA polymerase II, that is defective in activator-dependent transcription, but not defective in activator-independent, basal transcription. The mutant contains two amino-acid substitutions, C92R and A159G, that are both required for pronounced defects in activator-dependent transcription. Synthetic enhancement of phenotypes of C92R and A159G, and of several other pairs of substitutions, is consistent with a functional relationship between residues 92-95 and 159-161. Homology modeling of RPB3 on the basis of the crystallographic structure of alphaNTD indicates that residues 92-95 and 159-162 are likely to be adjacent within the structure of RPB3. In addition, homology modeling indicates that the location of residues 159-162 within RPB3 corresponds to the location of an activation target within alphaNTD (the target of activating region 2 of catabolite activator protein, an activation target involved in a protein-protein interaction that facilitates isomerization of the RNA polymerase promoter closed complex to the RNA polymerase promoter open complex). The apparent finding of a conserved surface required for activation in eukaryotes and bacteria raises the possibility of conserved mechanisms of activation in eukaryotes and bacteria.

Published

2000

47. Intermediates in formation and activity of the RNA polymerase II preinitiation complex: holoenzyme recruitment and a postrecruitment role for the TATA box and TFIIB.

Author

Ranish JA, Yudkovsky N, and Hahn S

Subjects

Fungal Proteins genetics, Mutation genetics, Promoter Regions, Genetic genetics, Protein Binding genetics, Trans-Activators genetics, Transcription Factor TFIIA, Transcription Factor TFIIB, Transcription Factor TFIID, Transcription Factors, TFII genetics, Transcription, Genetic genetics, Transcriptional Activation genetics, RNA Polymerase II genetics, TATA Box genetics, Transcription Factors genetics

Abstract

Assembly and activity of yeast RNA polymerase II (Pol II) preinitiation complexes (PIC) was investigated with an immobilized promoter assay and extracts made from wild-type cells and from cells containing conditional mutations in components of the Pol II machinery. We describe the following findings: (1) In one step, TFIID and TFIIA assemble at the promoter independently of holoenzyme. In another step, holoenzyme is recruited to the promoter. Mutations in the CTD of Pol II, Srb2, Srb4, and Srb5, and two mutations in TFIIB disrupt recruitment of all holoenzyme components tested without affecting TFIID and TFIIA recruitment. These results indicate that the stepwise assembly pathway is blocked after TFIID/TFIIA binding. (2) Both the Gal4-AH and Gal4-VP16 activators stimulate formation of active PICs by increasing the extent of PIC formation. The Gal4-AH activator stimulated PIC formation by enhancing the binding of TFIID and TFIIA, whereas Gal4-VP16 could enhance the recruitment of TFIID, TFIIA, and holoenzyme. (3) Extracts deficient in TFIIA activity showed reduced assembly of all PIC components. These and other results suggest that TFIIA acts at an early step by enhancing the stable recruitment of TFIID. (4) An extract containing the TFIIB mutant E62G, had no defect in PIC formation, but had a severe defect in transcription. Similarly, mutation of the TATA box reduced PIC formation only two- to fourfold, but severely compromised transcription. These results demonstate an involvement of TFIIB and the TATA box in one or more steps after recruitment of factors to the promoter.

Published

1999

48. The Oct-1 POU domain activates snRNA gene transcription by contacting a region in the SNAPc largest subunit that bears sequence similarities to the Oct-1 coactivator OBF-1.

Author

Ford E, Strubin M, and Hernandez N

Subjects

Amino Acid Sequence, Binding Sites genetics, DNA Probes genetics, DNA Probes metabolism, DNA-Binding Proteins metabolism, Homeodomain Proteins genetics, Host Cell Factor C1, Humans, Molecular Sequence Data, Mutation genetics, Octamer Transcription Factor-1, Promoter Regions, Genetic genetics, Protein Binding genetics, RNA Polymerase II genetics, RNA Polymerase III genetics, Trans-Activators metabolism, Transcription Factors metabolism, DNA-Binding Proteins genetics, RNA, Small Nuclear genetics, Trans-Activators genetics, Transcription Factors genetics, Transcriptional Activation genetics

Abstract

The RNA polymerases II and III snRNA gene promoters contain an octamer sequence as part of the enhancer and a proximal sequence element (PSE) as part of the core promoter. The octamer and the PSE bind the POU domain activator Oct-1 and the basal transcription factor SNAPc, respectively. Oct-1, but not Oct-1 with a single E7R mutation within the POU domain, binds cooperatively with SNAPc and, in effect, recruits SNAPc to the PSE. Here, we show that SNAPc recruitment is mediated by an interaction between the Oct-1 POU domain and a small region of the largest subunit of SNAPc, SNAP190. This SNAP190 region is strikingly similar to a region in the B-cell-specific Oct-1 coactivator, OBF-1, that is required for interaction with octamer-bound Oct-1 POU domain. The Oct-1 POU domain-SNAP190 interaction is a direct protein-protein contact as determined by the isolation of a switched specificity SNAP190 mutant that interacts with Oct-1 POU E7R but not with wild-type Oct-1 POU. We also show that this direct protein-protein contact results in activation of transcription. Thus, we have identified an activation target of a human activator, Oct-1, within its cognate basal transcription complex.

Published

1998

49. Allosteric interactions between capping enzyme subunits and the RNA polymerase II carboxy-terminal domain.

Author

Cho EJ, Rodriguez CR, Takagi T, and Buratowski S

Subjects

Acid Anhydride Hydrolases genetics, Allosteric Regulation genetics, Fungal Proteins genetics, Gene Expression Regulation, Fungal genetics, Genes, Fungal genetics, Mutation genetics, Recombinant Proteins genetics, Nucleotidyltransferases genetics, RNA Polymerase II genetics, Saccharomyces cerevisiae enzymology

Abstract

mRNA capping is a cotranscriptional event mediated by the association of capping enzyme with the phosphorylated carboxy-terminal domain (CTD) of RNA polymerase II. In the yeast Saccharomyces cerevisiae, capping enzyme is composed of two subunits, the mRNA 5'-triphosphatase (Cet1) and the mRNA guanylyltransferase (Ceg1). Here we map interactions between Ceg1, Cet1, and the CTD. Although the guanylyltransferase subunit can bind alone to the CTD, it cannot be guanylylated unless the triphosphatase subunit is also present. Therefore, the yeast mRNA guanylyltransferase is regulated by allosteric interactions with both the triphosphatase and CTD.

Published

1998

50. mRNA capping enzyme is recruited to the transcription complex by phosphorylation of the RNA polymerase II carboxy-terminal domain.

Author

Cho EJ, Takagi T, Moore CR, and Buratowski S

Subjects

Binding Sites, Nucleotidyltransferases genetics, Phosphorylation, RNA Polymerase II genetics, RNA, Messenger metabolism, Recombinant Proteins genetics, Recombinant Proteins metabolism, Transcription Factor TFIIH, Transcription Factors genetics, Transcription Factors metabolism, Nucleotidyltransferases metabolism, RNA Polymerase II metabolism, Transcription Factors, TFII, Transcription, Genetic

Abstract

Capping of mRNA occurs shortly after transcription initiation, preceding other mRNA processing events such as mRNA splicing and polyadenylation. To determine the mechanism of coupling between transcription and capping, we tested for a physical interaction between capping enzyme and the transcription machinery. Capping enzyme is not stably associated with basal transcription factors or the RNA polymerase II (Pol II) holoenzyme. However, capping enzyme can directly and specifically interact with the phosphorylated form of the RNA polymerase carboxy-terminal domain (CTD). This association occurs in the context of the transcription initiation complex and is blocked by the CTD-kinase inhibitor H8. Furthermore, conditional truncation mutants of the Pol II CTD are lethal when combined with a capping enzyme mutant. Our results provide in vitro and in vivo evidence that capping enzyme is recruited to the transcription complex via phosphorylation of the RNA polymerase CTD.

Published

1997