Your search keyword '"RNA Polymerase II"' showing total 8,024 results

1. Structural basis of transcription: RNA polymerase II substrate binding and metal coordination using a free-electron laser.

Author

Lin G, Barnes CO, Weiss S, Dutagaci B, Qiu C, Feig M, Song J, Lyubimov A, Cohen AE, Kaplan CD, and Calero G

Subjects

Lasers, Protein Conformation, Electrons, Protein Binding, Adenosine Triphosphate metabolism, Adenosine Triphosphate chemistry, Binding Sites, RNA Polymerase II metabolism, RNA Polymerase II chemistry, RNA Polymerase II genetics, Catalytic Domain, Magnesium metabolism, Magnesium chemistry, Molecular Dynamics Simulation, Transcription, Genetic

Abstract

Catalysis and translocation of multisubunit DNA-directed RNA polymerases underlie all cellular mRNA synthesis. RNA polymerase II (Pol II) synthesizes eukaryotic pre-mRNAs from a DNA template strand buried in its active site. Structural details of catalysis at near-atomic resolution and precise arrangement of key active site components have been elusive. Here, we present the free-electron laser (FEL) structures of a matched ATP-bound Pol II and the hyperactive Rpb1 T834P bridge helix (BH) mutant at the highest resolution to date. The radiation-damage-free FEL structures reveal the full active site interaction network, including the trigger loop (TL) in the closed conformation, bonafide occupancy of both site A and B Mg 2+ , and, more importantly, a putative third (site C) Mg 2+ analogous to that described for some DNA polymerases but not observed previously for cellular RNA polymerases. Molecular dynamics (MD) simulations of the structures indicate that the third Mg 2+ is coordinated and stabilized at its observed position. TL residues provide half of the substrate binding pocket while multiple TL/BH interactions induce conformational changes that could allow translocation upon substrate hydrolysis. Consistent with TL/BH communication, a FEL structure and MD simulations of the T834P mutant reveal rearrangement of some active site interactions supporting potential plasticity in active site function and long-distance effects on both the width of the central channel and TL conformation, likely underlying its increased elongation rate at the expense of fidelity., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

2. SOX2 represses c-MYC transcription by altering the co-activator landscape of the c-MYC super-enhancer and promoter regions.

Author

Ormsbee Golden BD, Gonzalez DV, Yochum GS, Coulter DW, and Rizzino A

Subjects

Humans, Cell Line, Tumor, Gene Expression Regulation, Neoplastic, Nuclear Proteins metabolism, Nuclear Proteins genetics, E1A-Associated p300 Protein metabolism, E1A-Associated p300 Protein genetics, Bromodomain Containing Proteins, SOXB1 Transcription Factors metabolism, SOXB1 Transcription Factors genetics, Promoter Regions, Genetic, Proto-Oncogene Proteins c-myc metabolism, Proto-Oncogene Proteins c-myc genetics, Transcription Factors metabolism, Transcription Factors genetics, Enhancer Elements, Genetic, Cell Cycle Proteins metabolism, Cell Cycle Proteins genetics, Transcription, Genetic

Abstract

Our previous studies determined that elevating SOX2 in a wide range of tumor cells leads to a reversible state of tumor growth arrest. Efforts to understand how tumor cell growth is inhibited led to the discovery of a SOX2:MYC axis that is responsible for downregulating c-MYC (MYC) when SOX2 is elevated. Although we had determined that elevating SOX2 downregulates MYC transcription, the mechanism responsible was not determined. Given the challenges of targeting MYC clinically, we set out to identify how elevating SOX2 downregulates MYC transcription. In this study, we focused on the MYC promoter region and an upstream region of the MYC locus that contains a MYC super-enhancer encompassing five MYC enhancers and which is associated with several cancers. Here we report that BRD4 and p300 associate with each of the MYC enhancers in the upstream MYC super-enhancer as well as the MYC promoter region and that elevating SOX2 decreases the recruitment of BRD4 and p300 to these sites. Additionally, we determined that elevating SOX2 leads to increases in the association of SOX2 and H3K27me3 within the MYC super-enhancer and the promoter region of MYC. Importantly, we conclude that the increases in SOX2 within the MYC super-enhancer precipitate a cascade of events that culminates in the repression of MYC transcription. Together, our studies identify a novel molecular mechanism able to regulate MYC transcription in two distinctly different tumor types and provide new mechanistic insights into the molecular interrelationships between two master regulators, SOX2 and MYC, widely involved in multiple cancers., Competing Interests: Conflicts of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

3. Live-cell imaging of RNA Pol II and elongation factors distinguishes competing mechanisms of transcription regulation.

Author

Versluis P, Graham TGW, Eng V, Ebenezer J, Darzacq X, Zipfel WR, and Lis JT

Subjects

Animals, HSP70 Heat-Shock Proteins metabolism, HSP70 Heat-Shock Proteins genetics, Positive Transcriptional Elongation Factor B metabolism, Positive Transcriptional Elongation Factor B genetics, Promoter Regions, Genetic, CRISPR-Cas Systems, Transcription Factors metabolism, Transcription Factors genetics, Polytene Chromosomes genetics, Polytene Chromosomes metabolism, Gene Expression Regulation, Phosphorylation, Protein Binding, Heat-Shock Response genetics, Nuclear Proteins metabolism, Nuclear Proteins genetics, Nucleosomes metabolism, Nucleosomes genetics, RNA Polymerase II metabolism, RNA Polymerase II genetics, Drosophila melanogaster genetics, Drosophila melanogaster metabolism, Drosophila Proteins genetics, Drosophila Proteins metabolism, Transcription, Genetic, Transcriptional Elongation Factors metabolism, Transcriptional Elongation Factors genetics

Abstract

RNA polymerase II (RNA Pol II)-mediated transcription is a critical, highly regulated process aided by protein complexes at distinct steps. Here, to investigate RNA Pol II and transcription-factor-binding and dissociation dynamics, we generated endogenous photoactivatable-GFP (PA-GFP) and HaloTag knockins using CRISPR-Cas9, allowing us to track a population of molecules at the induced Hsp70 loci in Drosophila melanogaster polytene chromosomes. We found that early in the heat-shock response, little RNA Pol II and DRB sensitivity-inducing factor (DSIF) are reused for iterative rounds of transcription. Surprisingly, although PAF1 and Spt6 are found throughout the gene body by chromatin immunoprecipitation (ChIP) assays, they show markedly different binding behaviors. Additionally, we found that PAF1 and Spt6 are only recruited after positive transcription elongation factor (P-TEFb)-mediated phosphorylation and RNA Pol II promoter-proximal pause escape. Finally, we observed that PAF1 may be expendable for transcription of highly expressed genes where nucleosome density is low. Thus, our live-cell imaging data provide key constraints to mechanistic models of transcription regulation., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

4. Human RNA Polymerase II Segregates from Genes and Nascent RNA and Transcribes in the Presence of DNA-Bound dCas9.

Author

Pessoa J and Carvalho C

Subjects

Humans, DNA metabolism, DNA genetics, Promoter Regions, Genetic, CRISPR-Associated Protein 9 metabolism, CRISPR-Associated Protein 9 genetics, CRISPR-Cas Systems, RNA genetics, RNA metabolism, RNA, Guide, CRISPR-Cas Systems genetics, RNA, Messenger genetics, RNA, Messenger metabolism, Cell Line, RNA Polymerase II metabolism, RNA Polymerase II genetics, Transcription, Genetic, beta-Globins genetics, beta-Globins metabolism

Abstract

RNA polymerase II (Pol II) dysfunction is frequently implied in human disease. Understanding its functional mechanism is essential for designing innovative therapeutic strategies. To visualize its supra-molecular interactions with genes and nascent RNA, we generated a human cell line carrying ~335 consecutive copies of a recombinant β-globin gene. Confocal microscopy showed that Pol II was not homogeneously concentrated around these identical gene copies. Moreover, Pol II signals partially overlapped with the genes and their nascent RNA, revealing extensive compartmentalization. Using a cell line carrying a single copy of the β-globin gene, we also tested if the binding of catalytically dead CRISPR-associated system 9 (dCas9) to different gene regions affected Pol II transcriptional activity. We assessed Pol II localization and nascent RNA levels using chromatin immunoprecipitation and droplet digital reverse transcription PCR, respectively. Some enrichment of transcriptionally paused Pol II accumulated in the promoter region was detected in a strand-specific way of gRNA binding, and there was no decrease in nascent RNA levels. Pol II preserved its transcriptional activity in the presence of DNA-bound dCas9. Our findings contribute further insight into the complex mechanism of mRNA transcription in human cells.

Published

2024

5. Defining a chromatin architecture that supports transcription at RNA polymerase II promoters.

Author

Fisher MJ and Luse DS

Subjects

Humans, Animals, Transcription Initiation Site, RNA Polymerase II metabolism, RNA Polymerase II genetics, Promoter Regions, Genetic, Nucleosomes metabolism, Nucleosomes genetics, Histones metabolism, Histones genetics, Transcription, Genetic, Transcription Factor TFIID metabolism, Transcription Factor TFIID genetics, Chromatin metabolism, Chromatin genetics

Abstract

Mammalian RNA polymerase II preinitiation complexes assemble adjacent to a nucleosome whose proximal edge (NPE) is typically 40 to 50 bp downstream of the transcription start site. At active promoters, that +1 nucleosome is universally modified by trimethylation on lysine 4 of histone H3 (H3K4me3). The Pol II preinitiation complex only extends 35 bp beyond the transcription start site, but nucleosomal templates with an NPE at +51 are nearly inactive in vitro with promoters that lack a TATA element and thus depend on TFIID for promoter recognition. Significantly, this inhibition is relieved when the +1 nucleosome contains H3K4me3, which can interact with TFIID subunits. Here, we show that H3K4me3 templates with both TATA and TATA-less promoters are active with +35 NPEs when transcription is driven by TFIID. Templates with +20 NPE are also active but at reduced levels compared to +35 and +51 NPEs, consistent with a general inhibition of promoter function when the proximal nucleosome encroaches on the preinitiation complex. Remarkably, dinucleosome templates support transcription when H3K4me3 is only present in the distal nucleosome, suggesting that TFIID-H3K4me3 interaction does not require modification of the +1 nucleosome. Transcription reactions performed with an alternative protocol retaining most nuclear factors results primarily in early termination, with a minority of complexes successfully traversing the first nucleosome. In such reactions, the +1 nucleosome does not substantially affect the level of termination even with an NPE of +20, indicating that a nucleosome barrier is not a major driver of early termination by Pol II., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

6. MECP2 directly interacts with RNA polymerase II to modulate transcription in human neurons.

Author

Liu Y, Flamier A, Bell GW, Diao AJ, Whitfield TW, Wang HC, Wu Y, Schulte F, Friesen M, Guo R, Mitalipova M, Liu XS, Vos SM, Young RA, and Jaenisch R

Subjects

Humans, Promoter Regions, Genetic, Rett Syndrome genetics, Rett Syndrome metabolism, CpG Islands genetics, Mutation, Gene Expression Regulation genetics, RNA Polymerase II metabolism, RNA Polymerase II genetics, Methyl-CpG-Binding Protein 2 metabolism, Methyl-CpG-Binding Protein 2 genetics, Neurons metabolism, Transcription, Genetic

Abstract

Mutations in the methyl-DNA-binding protein MECP2 cause the neurodevelopmental disorder Rett syndrome (RTT). How MECP2 contributes to transcriptional regulation in normal and disease states is unresolved; it has been reported to be an activator and a repressor. We describe here the first integrated CUT&Tag, transcriptome, and proteome analyses using human neurons with wild-type (WT) and mutant MECP2 molecules. MECP2 occupies CpG-rich promoter-proximal regions in over four thousand genes in human neurons, including a plethora of autism risk genes, together with RNA polymerase II (RNA Pol II). MECP2 directly interacts with RNA Pol II, and genes occupied by both proteins showed reduced expression in neurons with MECP2 patient mutations. We conclude that MECP2 acts as a positive cofactor for RNA Pol II gene expression at many neuronal genes that harbor CpG islands in promoter-proximal regions and that RTT is due, in part, to the loss of gene activity of these genes in neurons., Competing Interests: Declaration of interests R.J. is an advisor and co-founder of Fate Therapeutics and Fulcrum Therapeutics. A.F. is a co-founder and shareholder of StemAxon. R.A.Y. is a founder and shareholder of Syros Pharmaceuticals, Camp4 Therapeutics, Omega Therapeutics, Dewpoint Therapeutics, and Paratus Sciences., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

7. FACT maintains chromatin architecture and thereby stimulates RNA polymerase II pausing during transcription in vivo.

Author

Žumer K, Ochmann M, Aljahani A, Zheenbekova A, Devadas A, Maier KC, Rus P, Neef U, Oudelaar AM, and Cramer P

Subjects

Humans, DNA-Binding Proteins metabolism, DNA-Binding Proteins genetics, Transcription Factors metabolism, Transcription Factors genetics, HeLa Cells, Chromatin Assembly and Disassembly, HEK293 Cells, Transcription Elongation, Genetic, Transcription Termination, Genetic, RNA Polymerase II metabolism, RNA Polymerase II genetics, Transcriptional Elongation Factors metabolism, Transcriptional Elongation Factors genetics, Chromatin metabolism, Chromatin genetics, Promoter Regions, Genetic, Nucleosomes metabolism, Nucleosomes genetics, High Mobility Group Proteins metabolism, High Mobility Group Proteins genetics, Transcription, Genetic

Abstract

Facilitates chromatin transcription (FACT) is a histone chaperone that supports transcription through chromatin in vitro, but its functional roles in vivo remain unclear. Here, we analyze the in vivo functions of FACT with the use of multi-omics analysis after rapid FACT depletion from human cells. We show that FACT depletion destabilizes chromatin and leads to transcriptional defects, including defective promoter-proximal pausing and elongation, and increased premature termination of RNA polymerase II. Unexpectedly, our analysis revealed that promoter-proximal pausing depends not only on the negative elongation factor (NELF) but also on the +1 nucleosome, which is maintained by FACT., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

8. Global control of RNA polymerase II.

Author

Gillis A and Berry S

Subjects

Humans, Gene Expression Regulation, Cell Nucleus metabolism, RNA, Messenger metabolism, RNA, Messenger genetics, Active Transport, Cell Nucleus, Animals, RNA Polymerase II metabolism, Transcription, Genetic

Abstract

RNA polymerase II (Pol II) is the multi-protein complex responsible for transcribing all protein-coding messenger RNA (mRNA). Most research on gene regulation is focused on the mechanisms controlling which genes are transcribed when, or on the mechanics of transcription. How global Pol II activity is determined receives comparatively less attention. Here, we follow the life of a Pol II molecule from 'assembly of the complex' to nuclear import, enzymatic activity, and degradation. We focus on how Pol II spends its time in the nucleus, and on the two-way relationship between Pol II abundance and activity in the context of homeostasis and global transcriptional changes., Competing Interests: Declaration of competing interest The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: Scott Berry reports financial support was provided by Australian Research Council. If there are other authors, they declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2024

9. Collaborators or competitors: the communication between RNA polymerase II and the nucleosome during eukaryotic transcription.

Author

Hardtke HA and Zhang YJ

Subjects

Humans, Animals, Histones metabolism, Histones chemistry, Histones genetics, Eukaryota genetics, Eukaryota enzymology, Eukaryota metabolism, Cryoelectron Microscopy, Signal Transduction, RNA Polymerase II metabolism, RNA Polymerase II chemistry, RNA Polymerase II genetics, Nucleosomes metabolism, Nucleosomes chemistry, Transcription, Genetic

Abstract

Decades of scientific research have been devoted to unraveling the intricacies of eukaryotic transcription since the groundbreaking discovery of eukaryotic RNA polymerases in the late 1960s. RNA polymerase II, the polymerase responsible for mRNA synthesis, has always attracted the most attention. Despite its structural resemblance to its bacterial counterpart, eukaryotic RNA polymerase II faces a unique challenge in progressing transcription due to the presence of nucleosomes that package DNA in the nuclei. In this review, we delve into the impact of RNA polymerase II and histone signaling on the progression of eukaryotic transcription. We explore the pivotal points of interactions that bridge the RNA polymerase II and histone signaling systems. Finally, we present an analysis of recent cryo-electron microscopy structures, which captured RNA polymerase II-nucleosome complexes at different stages of the transcription cycle. The combination of the signaling crosstalk and the direct visualization of RNA polymerase II-nucleosome complexes provides a deeper understanding of the communication between these two major players in eukaryotic transcription.

Published

2024

10. An emerging paradigm in epigenetic marking: coordination of transcription and replication.

Author

Fenstermaker TK, Petruk S, and Mazo A

Subjects

Animals, Chromatin metabolism, Chromatin genetics, DNA metabolism, DNA genetics, Eukaryota genetics, Eukaryota metabolism, DNA Replication genetics, DNA-Directed RNA Polymerases metabolism, DNA-Directed RNA Polymerases genetics, Epigenesis, Genetic, Transcription, Genetic genetics

Abstract

DNA replication and RNA transcription both utilize DNA as a template and therefore need to coordinate their activities. The predominant theory in the field is that in order for the replication fork to proceed, transcription machinery has to be evicted from DNA until replication is complete. If that does not occur, these machineries collide, and these collisions elicit various repair mechanisms which require displacement of one of the enzymes, often RNA polymerase, in order for replication to proceed. This model is also at the heart of the epigenetic bookmarking theory, which implies that displacement of RNA polymerase during replication requires gradual re-building of chromatin structure, which guides recruitment of transcriptional proteins and resumption of transcription. We discuss these theories but also bring to light newer data that suggest that these two processes may not be as detrimental to one another as previously thought. This includes findings suggesting that these processes can occur without fork collapse and that RNA polymerase may only be transiently displaced during DNA replication. We discuss potential mechanisms by which RNA polymerase may be retained at the replication fork and quickly rebind to DNA post-replication. These discoveries are important, not only as new evidence as to how these two processes are able to occur harmoniously but also because they have implications on how transcriptional programs are maintained through DNA replication. To this end, we also discuss the coordination of replication and transcription in light of revising the current epigenetic bookmarking theory of how the active gene status can be transmitted through S phase.

Published

2024

11. Direct observation of a condensate effect on super-enhancer controlled gene bursting.

Author

Du M, Stitzinger SH, Spille JH, Cho WK, Lee C, Hijaz M, Quintana A, and Cissé II

Subjects

DNA genetics, Enhancer Elements, Genetic, Animals, Mice, Embryonic Stem Cells metabolism, Microscopy methods, Gene Expression Regulation, Super Enhancers, Transcription, Genetic, SOXB1 Transcription Factors genetics

Abstract

Enhancers are distal DNA elements believed to loop and contact promoters to control gene expression. Recently, we found diffraction-sized transcriptional condensates at genes controlled by clusters of enhancers (super-enhancers). However, a direct function of endogenous condensates in controlling gene expression remains elusive. Here, we develop live-cell super-resolution and multi-color 3D-imaging approaches to investigate putative roles of endogenous condensates in the regulation of super-enhancer controlled gene Sox2. In contrast to enhancer distance, we find instead that the condensate's positional dynamics are a better predictor of gene expression. A basal gene bursting occurs when the condensate is far (>1 μm), but burst size and frequency are enhanced when the condensate moves in proximity (<1 μm). Perturbations of cohesin and local DNA elements do not prevent basal bursting but affect the condensate and its burst enhancement. We propose a three-way kissing model whereby the condensate interacts transiently with gene locus and regulatory DNA elements to control gene bursting., Competing Interests: Declaration of interests I.I.C. is on the Advisory Board at Cell., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

12. Restrictor synergizes with Symplekin and PNUTS to terminate extragenic transcription.

Author

Russo M, Piccolo V, Polizzese D, Prosperini E, Borriero C, Polletti S, Bedin F, Marenda M, Michieletto D, Mandana GM, Rodighiero S, Cuomo A, and Natoli G

Subjects

Animals, Regulatory Sequences, Nucleic Acid, RNA-Binding Proteins metabolism, Protein Processing, Post-Translational, Mammals genetics, RNA Polymerase II metabolism, Transcription, Genetic

Abstract

Transcription termination pathways mitigate the detrimental consequences of unscheduled promiscuous initiation occurring at hundreds of thousands of genomic cis -regulatory elements. The Restrictor complex, composed of the Pol II-interacting protein WDR82 and the RNA-binding protein ZC3H4, suppresses processive transcription at thousands of extragenic sites in mammalian genomes. Restrictor-driven termination does not involve nascent RNA cleavage, and its interplay with other termination machineries is unclear. Here we show that efficient termination at Restrictor-controlled extragenic transcription units involves the recruitment of the protein phosphatase 1 (PP1) regulatory subunit PNUTS, a negative regulator of the SPT5 elongation factor, and Symplekin, a protein associated with RNA cleavage complexes but also involved in cleavage-independent and phosphatase-dependent termination of noncoding RNAs in yeast. PNUTS and Symplekin act synergistically with, but independently from, Restrictor to dampen processive extragenic transcription. Moreover, the presence of limiting nuclear levels of Symplekin imposes a competition for its recruitment among multiple transcription termination machineries, resulting in mutual regulatory interactions. Hence, by synergizing with Restrictor, Symplekin and PNUTS enable efficient termination of processive, long-range extragenic transcription., (© 2023 Russo et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2023

13. Hitting the brakes on transcription to extend lifespan.

Author

Burkewitz K

Subjects

Animals, Humans, Aged, RNA Polymerase II genetics, RNA Polymerase II metabolism, Nucleosomes, Alternative Splicing, Transcription, Genetic, Longevity genetics

Abstract

In aged animals from worms to humans, transcriptional elongation rates are faster, leading to changes in transcript quality and alternative splicing. Recent work by Debès et al. shows how interventions that slow elongation rates, such as mutating RNA polymerase II (Pol II) or increasing nucleosome density to impose transcriptional 'traffic', delay senescence and promote longevity., Competing Interests: Declaration of Interests None declared by author., (Copyright © 2023 Elsevier Ltd. All rights reserved.)

Published

2023

14. RNA polymerase II dynamics and mRNA stability feedback scale mRNA amounts with cell size.

Author

Swaffer MP, Marinov GK, Zheng H, Fuentes Valenzuela L, Tsui CY, Jones AW, Greenwood J, Kundaje A, Greenleaf WJ, Reyes-Lamothe R, and Skotheim JM

Subjects

Feedback, RNA Stability, RNA, Messenger genetics, RNA, Messenger metabolism, Cell Size, RNA Polymerase II metabolism, Transcription, Genetic

Abstract

A fundamental feature of cellular growth is that total protein and RNA amounts increase with cell size to keep concentrations approximately constant. A key component of this is that global transcription rates increase in larger cells. Here, we identify RNA polymerase II (RNAPII) as the limiting factor scaling mRNA transcription with cell size in budding yeast, as transcription is highly sensitive to the dosage of RNAPII but not to other components of the transcriptional machinery. Our experiments support a dynamic equilibrium model where global RNAPII transcription at a given size is set by the mass action recruitment kinetics of unengaged nucleoplasmic RNAPII to the genome. However, this only drives a sub-linear increase in transcription with size, which is then partially compensated for by a decrease in mRNA decay rates as cells enlarge. Thus, limiting RNAPII and feedback on mRNA stability work in concert to scale mRNA amounts with cell size., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2023

15. Elongation rate of RNA polymerase II affects pausing patterns across 3' UTRs.

Author

Khitun A, Brion C, Moqtaderi Z, Geisberg JV, Churchman LS, and Struhl K

Subjects

Polyadenylation, Transcription Factors metabolism, Mutation, 3' Untranslated Regions genetics, RNA Polymerase II genetics, RNA Polymerase II metabolism, Transcription, Genetic genetics, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism

Abstract

Yeast mRNAs are polyadenylated at multiple sites in their 3' untranslated regions (3' UTRs), and poly(A) site usage is regulated by the rate of transcriptional elongation by RNA polymerase II (Pol II). Slow Pol II derivatives favor upstream poly(A) sites, and fast Pol II derivatives favor downstream poly(A) sites. Transcriptional elongation and polyadenylation are linked at the nucleotide level, presumably reflecting Pol II dwell time at each residue that influences the level of polyadenylation. Here, we investigate the effect of Pol II elongation rate on pausing patterns and the relationship between Pol II pause sites and poly(A) sites within 3' UTRs. Mutations that affect Pol II elongation rate alter sequence preferences at pause sites within 3' UTRs, and pausing preferences differ between 3' UTRs and coding regions. In addition, sequences immediately flanking the pause sites show preferences that are largely independent of Pol II speed. In wild-type cells, poly(A) sites are preferentially located < 50 nucleotides upstream from Pol II pause sites, but this spatial relationship is diminished in cells harboring Pol II speed mutants. Based on a random forest classifier, Pol II pause sites are modestly predicted by the distance to poly(A) sites but are better predicted by the chromatin landscape in Pol II speed derivatives. Transcriptional regulatory proteins can influence the relationship between Pol II pausing and polyadenylation but in a manner distinct from Pol II elongation rate derivatives. These results indicate a complex relationship between Pol II pausing and polyadenylation., Competing Interests: Conflict of interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

16. Enhancers, phase separation and the RNA polymerase II transfer model.

Author

Gelder K and Bose D

Subjects

Chromatin, Regulatory Sequences, Nucleic Acid, Enhancer Elements, Genetic genetics, RNA Polymerase II metabolism, Transcription, Genetic

Published

2023

17. Transcription factor IID parks and drives preinitiation complexes at sharp or broad promoters.

Author

Bernardini A, Hollinger C, Willgenss D, Müller F, Devys D, and Tora L

Subjects

Animals, TATA Box, Promoter Regions, Genetic, RNA Polymerase II metabolism, Transcription Factor TFIID genetics, Transcription Factor TFIID metabolism, Transcription, Genetic

Abstract

Core promoters are sites where transcriptional regulatory inputs of a gene are integrated to direct the assembly of the preinitiation complex (PIC) and RNA polymerase II (Pol II) transcription output. Until now, core promoter functions have been investigated by distinct methods, including Pol II transcription initiation site mappings and structural characterization of PICs on distinct promoters. Here, we bring together these previously unconnected observations and hypothesize how, on metazoan TATA promoters, the precisely structured building up of transcription factor (TF) IID-based PICs results in sharp transcription start site (TSS) selection; or, in contrast, how the less strictly controlled positioning of the TATA-less promoter DNA relative to TFIID-core PIC components results in alternative broad TSS selections by Pol II., Competing Interests: Declaration of interests No interests are declared., (Copyright © 2023 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2023

18. Driving forces behind phase separation of the carboxy-terminal domain of RNA polymerase II.

Author

Flores-Solis D, Lushpinskaia IP, Polyansky AA, Changiarath A, Boehning M, Mirkovic M, Walshe J, Pietrek LM, Cramer P, Stelzl LS, Zagrovic B, and Zweckstetter M

Subjects

Humans, Cell Nucleus, Cluster Analysis, Diet, Protein-Restricted, Eukaryota, RNA Polymerase II, Transcription, Genetic

Abstract

Eukaryotic gene regulation and pre-mRNA transcription depend on the carboxy-terminal domain (CTD) of RNA polymerase (Pol) II. Due to its highly repetitive, intrinsically disordered sequence, the CTD enables clustering and phase separation of Pol II. The molecular interactions that drive CTD phase separation and Pol II clustering are unclear. Here, we show that multivalent interactions involving tyrosine impart temperature- and concentration-dependent self-coacervation of the CTD. NMR spectroscopy, molecular ensemble calculations and all-atom molecular dynamics simulations demonstrate the presence of diverse tyrosine-engaging interactions, including tyrosine-proline contacts, in condensed states of human CTD and other low-complexity proteins. We further show that the network of multivalent interactions involving tyrosine is responsible for the co-recruitment of the human Mediator complex and CTD during phase separation. Our work advances the understanding of the driving forces of CTD phase separation and thus provides the basis to better understand CTD-mediated Pol II clustering in eukaryotic gene transcription., (© 2023. Springer Nature Limited.)

Published

2023

19. RNAPII response to transcription-blocking DNA lesions in mammalian cells.

Author

Wang J, Muste Sadurni M, and Saponaro M

Subjects

Animals, DNA Repair, DNA Damage, DNA genetics, DNA metabolism, Mammals genetics, Mammals metabolism, RNA Polymerase II genetics, RNA Polymerase II metabolism, Transcription, Genetic

Abstract

RNA polymerase II moves along genes to decode genetic information stored in the mammalian genome into messenger RNA and different forms of non-coding RNA. However, the transcription process is frequently challenged by DNA lesions caused by exogenous and endogenous insults, among which helix-distorting DNA lesions and double-stranded DNA breaks are particularly harmful for cell survival. In response to such DNA damage, RNA polymerase II transcription is regulated both locally and globally by multi-layer mechanisms, whereas transcription-blocking lesions are repaired before transcription can recover. Failure in DNA damage repair will cause genome instability and cell death. Although recent studies have expanded our understanding of RNA polymerase II regulation confronting DNA lesions, it is still not always clear what the direct contribution of RNA polymerase II is in the DNA damage repair processes. In this review, we focus on how RNA polymerase II and transcription are both repressed by transcription stalling lesions such as DNA-adducts and double strand breaks, as well as how they are actively regulated to support the cellular response to DNA damage and favour the repair of lesions., (© 2022 The Authors. The FEBS Journal published by John Wiley & Sons Ltd on behalf of Federation of European Biochemical Societies.)

Published

2023

20. A restrictor complex of ZC3H4, WDR82, and ARS2 integrates with PNUTS to control unproductive transcription.

Author

Estell C, Davidson L, Eaton JD, Kimura H, Gold VAM, and West S

Subjects

Humans, Cell Nucleus metabolism, RNA, Untranslated genetics, Chromosomal Proteins, Non-Histone genetics, Transcription, Genetic, RNA Polymerase II genetics, RNA Polymerase II metabolism

Abstract

The transcriptional termination of unstable non-coding RNAs (ncRNAs) is poorly understood compared to coding transcripts. We recently identified ZC3H4-WDR82 ("restrictor") as restricting human ncRNA transcription, but how it does this is unknown. Here, we show that ZC3H4 additionally associates with ARS2 and the nuclear exosome targeting complex. The domains of ZC3H4 that contact ARS2 and WDR82 are required for ncRNA restriction, suggesting their presence in a functional complex. Consistently, ZC3H4, WDR82, and ARS2 co-transcriptionally control an overlapping population of ncRNAs. ZC3H4 is proximal to the negative elongation factor, PNUTS, which we show enables restrictor function and is required to terminate the transcription of all major RNA polymerase II transcript classes. In contrast to short ncRNAs, longer protein-coding transcription is supported by U1 snRNA, which shields transcripts from restrictor and PNUTS at hundreds of genes. These data provide important insights into the mechanism and control of transcription by restrictor and PNUTS., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2023 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2023

21. A combinatorial approach to uncover an additional Integrator subunit.

Author

Offley SR, Pfleiderer MM, Zucco A, Fraudeau A, Welsh SA, Razew M, Galej WP, and Gardini A

Subjects

Transcription, Genetic, RNA Polymerase II metabolism

Abstract

RNA polymerase II (RNAPII) controls expression of all protein-coding genes and most noncoding loci in higher eukaryotes. Calibrating RNAPII activity requires an assortment of polymerase-associated factors that are recruited at sites of active transcription. The Integrator complex is one of the most elusive transcriptional regulators in metazoans, deemed to be recruited after initiation to help establish and modulate paused RNAPII. Integrator is known to be composed of 14 subunits that assemble and operate in a modular fashion. We employed proteomics and machine-learning structure prediction (AlphaFold2) to identify an additional Integrator subunit, INTS15. We report that INTS15 assembles primarily with the INTS13/14/10 module and interfaces with the Int-PP2A module. Functional genomics analysis further reveals a role for INTS15 in modulating RNAPII pausing at a subset of genes. Our study shows that omics approaches combined with AlphaFold2-based predictions provide additional insights into the molecular architecture of large and dynamic multiprotein complexes., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2023 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2023

22. Structure of an Intranucleosomal DNA Loop That Senses DNA Damage during Transcription.

Author

Gerasimova NS, Volokh OI, Pestov NA, Armeev GA, Kirpichnikov MP, Shaytan AK, Sokolova OS, and Studitsky VM

Subjects

Chromatin, DNA genetics, DNA Damage, Nucleosomes, Transcription, Genetic

Abstract

Transcription through chromatin by RNA polymerase II (Pol II) is accompanied by the formation of small intranucleosomal DNA loops containing the enzyme (i-loops) that are involved in survival of core histones on the DNA and arrest of Pol II during the transcription of damaged DNA. However, the structures of i-loops have not been determined. Here, the structures of the intermediates formed during transcription through a nucleosome containing intact or damaged DNA were studied using biochemical approaches and electron microscopy. After RNA polymerase reaches position +24 from the nucleosomal boundary, the enzyme can backtrack to position +20, where DNA behind the enzyme recoils on the surface of the histone octamer, forming an i-loop that locks Pol II in the arrested state. Since the i-loop is formed more efficiently in the presence of SSBs positioned behind the transcribing enzyme, the loop could play a role in the transcription-coupled repair of DNA damage hidden in the chromatin structure.

Published

2022

23. Genetic dissection of the RNA polymerase II transcription cycle.

Author

Chou SP, Alexander AK, Rice EJ, Choate LA, and Danko CG

Subjects

Animals, Mammals genetics, Mice, Promoter Regions, Genetic, RNA, Messenger metabolism, Transcription Initiation Site, RNA Polymerase II genetics, RNA Polymerase II metabolism, Transcription, Genetic

Abstract

How DNA sequence affects the dynamics and position of RNA Polymerase II (Pol II) during transcription remains poorly understood. Here, we used naturally occurring genetic variation in F1 hybrid mice to explore how DNA sequence differences affect the genome-wide distribution of Pol II. We measured the position and orientation of Pol II in eight organs collected from heterozygous F1 hybrid mice using ChRO-seq. Our data revealed a strong genetic basis for the precise coordinates of transcription initiation and promoter proximal pause, allowing us to redefine molecular models of core transcriptional processes. Our results implicate DNA sequence, including both known and novel DNA sequence motifs, as key determinants of the position of Pol II initiation and pause. We report evidence that initiation site selection follows a stochastic process similar to Brownian motion along the DNA template. We found widespread differences in the position of transcription termination, which impact the primary structure and stability of mature mRNA. Finally, we report evidence that allelic changes in transcription often affect mRNA and ncRNA expression across broad genomic domains. Collectively, we reveal how DNA sequences shape core transcriptional processes at single nucleotide resolution in mammals., Competing Interests: SC, AA, ER, LC, CD No competing interests declared, (© 2022, Chou et al.)

Published

2022

24. Transcription by RNA polymerase II and the CTD-chromatin crosstalk.

Author

Singh N, Asalam M, Ansari MO, Gerasimova NS, Studitsky VM, and Akhtar MS

Subjects

Chromatin genetics, Phosphorylation, Protein Domains, RNA Polymerase II chemistry, RNA Polymerase II genetics, Saccharomycetales genetics, Saccharomycetales metabolism, Chromatin metabolism, RNA Polymerase II metabolism, Transcription, Genetic

Abstract

The epigenetic phenomenon is known to derive the phenotypic variation of an organism through an interconnected cellular network of histone modifications, DNA methylation and RNA regulatory network. Transcription for protein coding genes is a highly regulated process and carried out by a large multi-complex RNA Polymerase II. The carboxy terminal domain (CTD) of the largest subunit of RNA Polymerase II consists of a conserved and highly repetitive heptad sequence Tyr 1 -Ser 2 -Pro 3 -Thr 4 -Ser 5 -Pro 6 -Ser 7 . The epigenetically modified CTD is thought to selectively bind different protein complexes that participate in mRNA biogenesis and export. The CTD and chromatin appears to have a spatial relationship during the transcription cycle, where the epigenetic modifications of CTD not only influence the state of histone modification but also mediates CTD-chromatin crosstalk. In this mini review, we have surveyed and discussed current developments of RNA Polymerase II CTD and its new emerging crosstalk with chromatin, during the stage specific progression of RNA Polymerase II in transcription cycle. This review is mainly focussed on the insights in budding yeast., Competing Interests: Declaration of competing interest All the authors declare no conflict of interest., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published

2022

25. Spt5 histone binding activity preserves chromatin during transcription by RNA polymerase II.

Author

Evrin C, Serra-Cardona A, Duan S, Mukherjee PP, Zhang Z, and Labib KPM

Subjects

Nucleosomes genetics, Protein Binding genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Chromatin genetics, Chromatin Assembly and Disassembly genetics, Chromosomal Proteins, Non-Histone genetics, Histones genetics, RNA Polymerase II genetics, Transcription, Genetic genetics, Transcriptional Elongation Factors genetics

Abstract

Nucleosomes are disrupted transiently during eukaryotic transcription, yet the displaced histones must be retained and redeposited onto DNA, to preserve nucleosome density and associated histone modifications. Here, we show that the essential Spt5 processivity factor of RNA polymerase II (Pol II) plays a direct role in this process in budding yeast. Functional orthologues of eukaryotic Spt5 are present in archaea and bacteria, reflecting its universal role in RNA polymerase processivity. However, eukaryotic Spt5 is unique in having an acidic amino terminal tail (Spt5N) that is sandwiched between the downstream nucleosome and the upstream DNA that emerges from Pol II. We show that Spt5N contains a histone-binding motif that is required for viability in yeast cells and prevents loss of nucleosomal histones within actively transcribed regions. These findings indicate that eukaryotic Spt5 combines two essential activities, which together couple processive transcription to the efficient capture and re-deposition of nucleosomal histones., (© 2022 The Authors. Published under the terms of the CC BY 4.0 license.)

Published

2022

26. Control of non-productive RNA polymerase II transcription via its early termination in metazoans.

Author

Rouvière JO, Lykke-Andersen S, and Jensen TH

Subjects

Animals, Promoter Regions, Genetic, RNA genetics, RNA Polymerase II metabolism, Transcription, Genetic

Abstract

Transcription establishes the universal first step of gene expression where RNA is produced by a DNA-dependent RNA polymerase. The most versatile of eukaryotic RNA polymerases, RNA polymerase II (Pol II), transcribes a broad range of DNA including protein-coding and a variety of non-coding transcription units. Although Pol II can be configured as a durable enzyme capable of transcribing hundreds of kilobases, there is reliable evidence of widespread abortive Pol II transcription termination shortly after initiation, which is often followed by rapid degradation of the associated RNA. The molecular details underlying this phenomenon are still vague but likely reflect the action of quality control mechanisms on the early Pol II complex. Here, we summarize current knowledge of how and when such promoter-proximal quality control is asserted on metazoan Pol II., (© 2022 The Author(s). Published by Portland Press Limited on behalf of the Biochemical Society.)

Published

2022

27. Dynamic transcription regulation at the single-molecule level.

Author

Wang Z and Deng W

Subjects

Animals, DNA biosynthesis, Single Molecule Imaging, Single-Cell Analysis, Chromatin metabolism, Gene Expression Regulation genetics, Transcription Factors metabolism, Transcription, Genetic genetics

Abstract

Cell fate changes during development, differentiation, and reprogramming are largely controlled at the transcription level. The DNA-binding transcription factors (TFs) often act in a combinatorial fashion to alter chromatin states and drive cell type-specific gene expression. Recent advances in fluorescent microscopy technologies have enabled direct visualization of biomolecules involved in the process of transcription and its regulatory events at the single-molecule level in living cells. Remarkably, imaging and tracking individual TF molecules at high temporal and spatial resolution revealed that they are highly dynamic in searching and binding cognate targets, rather than static and binding constantly. In combination with investigation using techniques from biochemistry, structure biology, genetics, and genomics, a more well-rounded view of transcription regulation is emerging. In this review, we briefly cover the technical aspects of live-cell single-molecule imaging and focus on the biological relevance and interpretation of the single-molecule dynamic features of transcription regulatory events observed in the native chromatin environment of living eukaryotic cells. We also discuss how these dynamic features might shed light on mechanistic understanding of transcription regulation., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2022

28. Human FKBP5 Negatively Regulates Transcription through Inhibition of P-TEFb Complex Formation.

Author

Mall DP, Basu S, Ghosh K, Kumari N, Lahiri A, Paul S, and Biswas D

Subjects

Cyclin T metabolism, Cyclin-Dependent Kinase 9 metabolism, Cyclins genetics, Humans, Protein Serine-Threonine Kinases metabolism, RNA Polymerase II metabolism, Positive Transcriptional Elongation Factor B metabolism, Tacrolimus Binding Proteins metabolism, Transcription, Genetic genetics

Abstract

Although a large number of recent studies indicate strong association of FKBP5 (aka FKBP51) functions with various stress-related psychiatric disorders, the overall mechanisms are poorly understood. Beyond a few studies indicating its functions in regulating glucocorticoid receptor, and AKT signaling pathways, other functional roles (if any) are unclear. Here, we report an antiproliferative role of human FKBP5 through negative regulation of expression of proliferation-related genes. Mechanistically, we show that, owing to the same region of interaction on cyclin-dependent kinse 9 (CDK9), human FKBP5 directly competes with cyclin T1 for functional p ositive t ranscription e longation f actor b (P-TEFb) complex formation. In vitro biochemical assays, coupled with cell-based assays, showed a strong negative effect of FKBP5 on P-TEFb-mediated phosphorylation of diverse substrates. Consistently, FKBP5 knockdown showed enhanced P-TEFb complex formation that led to increased global RNA polymerase II C-terminal domain (CTD) phosphorylation, expression of proliferation-related genes, and subsequent proliferation. Thus, our results show an important role for FKBP5 in negative regulation of P-TEFb functions within mammalian cells.

Published

2022

29. RNA polymerase II trapped on a molecular treadmill: Structural basis of persistent transcriptional arrest by a minor groove DNA binder.

Author

Oh J, Jia T, Xu J, Chong J, Dervan PB, and Wang D

Subjects

Base Sequence, Imidazoles chemistry, Models, Molecular, Pyrroles chemistry, Transcriptional Elongation Factors metabolism, DNA chemistry, Nucleic Acid Conformation, RNA Polymerase II metabolism, Transcription, Genetic

Abstract

Elongating RNA polymerase II (Pol II) can be paused or arrested by a variety of obstacles. These obstacles include DNA lesions, DNA-binding proteins, and small molecules. Hairpin pyrrole-imidazole (Py-Im) polyamides bind to the minor groove of DNA in a sequence-specific manner and induce strong transcriptional arrest. Remarkably, this Py-Im-induced Pol II transcriptional arrest is persistent and cannot be rescued by transcription factor TFIIS. In contrast, TFIIS can effectively rescue the transcriptional arrest induced by a nucleosome barrier. The structural basis of Py-Im-induced transcriptional arrest and why TFIIS cannot rescue this arrest remain elusive. Here we determined the X-ray crystal structures of four distinct Pol II elongation complexes (Pol II ECs) in complex with hairpin Py-Im polyamides as well as of the hairpin Py-Im polyamides-dsDNA complex. We observed that the Py-Im oligomer directly interacts with RNA Pol II residues, introduces compression of the downstream DNA duplex, prevents Pol II forward translocation, and induces Pol II backtracking. These results, together with biochemical studies, provide structural insight into the molecular mechanism by which Py-Im blocks transcription. Our structural study reveals why TFIIS fails to promote Pol II bypass of Py-Im-induced transcriptional arrest., Competing Interests: The authors declare no competing interest., (Copyright © 2022 the Author(s). Published by PNAS.)

Published

2022

30. Merging Established Mechanisms with New Insights: Condensates, Hubs, and the Regulation of RNA Polymerase II Transcription.

Author

Palacio M and Taatjes DJ

Subjects

Biophysical Phenomena, Cell Nucleus chemistry, Cell Nucleus genetics, Genome, Human, Humans, Mutation, RNA genetics, RNA metabolism, RNA Polymerase II chemistry, Transcription Factors genetics, Transcription Factors metabolism, RNA chemistry, RNA Polymerase II genetics, RNA Polymerase II metabolism, Transcription, Genetic

Abstract

The regulation of RNA polymerase II (pol II) transcription requires a complex and context-specific array of proteins and protein complexes, as well as nucleic acids and metabolites. Every major physiological process requires coordinated transcription of specific sets of genes at the appropriate time, and a breakdown in this regulation is a hallmark of human disease. A proliferation of recent studies has revealed that many general transcription components, including sequence-specific, DNA-binding transcription factors, Mediator, and pol II itself, are capable of liquid-liquid phase separation, to form condensates that partition these factors away from the bulk aqueous phase. These findings hold great promise for next-level understanding of pol II transcription; however, many mechanistic aspects align with more conventional models, and whether phase separation per se regulates pol II activity in cells remains controversial. In this review, we describe the conventional and condensate-dependent models, and why their similarities and differences are important. We also compare and contrast these models in the context of genome organization and pol II transcription (initiation, elongation, and termination), and highlight the central role of RNA in these processes. Finally, we discuss mutations that disrupt normal partitioning of transcription factors, and how this may contribute to disease., Competing Interests: Competing interest statement D.J.T. is a member of the scientific advisory board at Dewpoint Therapeutics., (Copyright © 2021 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published

2022

31. RNA polymerase II is recruited to DNA double-strand breaks for dilncRNA transcription in Drosophila .

Author

Böttcher R, Schmidts I, Nitschko V, Duric P, and Förstemann K

Subjects

Animals, DNA Repair, Gene Expression Regulation, Introns, Protein Binding, RNA Polymerase III metabolism, RNA Splicing, RNA, Small Interfering genetics, Sequence Analysis, DNA, DNA Breaks, Double-Stranded, Drosophila genetics, Drosophila metabolism, RNA Polymerase II metabolism, RNA, Long Noncoding genetics, Transcription, Genetic

Abstract

DNA double-strand breaks are among the most toxic lesions that can occur in a genome and their faithful repair is thus of great importance. Recent findings have uncovered local transcription that initiates at the break and forms a non-coding transcript, called damage-induced long non-coding RNA (dilncRNA), which helps to coordinate the DNA transactions necessary for repair. We provide nascent RNA sequencing-based evidence that RNA polymerase II transcribes the dilncRNA in Drosophila and that this is more efficient for DNA breaks in an intron-containing gene, consistent with the higher damage-induced siRNA levels downstream of an intron. The spliceosome thus stimulates recruitment of RNA polymerase II to the break, rather than merely promoting the annealing of sense and antisense RNA to form the siRNA precursor. In contrast, RNA polymerase III nascent RNA libraries did not contain reads corresponding to the cleaved loci and selective inhibition of RNA polymerase III did not reduce the yield of damage-induced siRNAs. Finally, the damage-induced siRNA density was unchanged downstream of a T8 sequence, which terminates RNA polymerase III transcription. We thus found no evidence for a participation of RNA polymerase III in dilncRNA transcription in cultured Drosophila cells.

Published

2022

32. Transcription-coupled DNA double-strand break repair.

Author

Guha S and Bhaumik SR

Subjects

DNA metabolism, DNA End-Joining Repair, Eukaryota genetics, Humans, Recombinational DNA Repair, DNA Breaks, Double-Stranded, DNA Repair, Transcription, Genetic

Abstract

The genomic DNA is constantly under attack by cellular and/or environmental factors. Fortunately, the cell is armed to safeguard its genome by various mechanisms such as nucleotide excision, base excision, mismatch and DNA double-strand break repairs. While these processes maintain the integrity of the genome throughout, DNA repair occurs preferentially faster at the transcriptionally active genes. Such transcription-coupled repair phenomenon plays important roles to maintain active genome integrity, failure of which would interfere with transcription, leading to an altered gene expression (and hence cellular pathologies/diseases). Among the various DNA damages, DNA double-strand breaks are quite toxic to the cells. If DNA double-strand break occurs at the active gene, it would interfere with transcription/gene expression, thus threatening cellular viability. Such DNA double-strand breaks are found to be repaired faster at the active gene in comparison to its inactive state or the inactive gene, thus supporting the existence of a new phenomenon of transcription-coupled DNA double-strand break repair. Here, we describe the advances of this repair process., (Published by Elsevier B.V.)

Published

2022

33. High-Resolution Deep Sequencing of Nascent Transcription in Yeast with BioGRO-seq.

Author

Jordán-Pla A and Pérez-Ortín JE

Subjects

DNA, DNA-Directed RNA Polymerases genetics, DNA-Directed RNA Polymerases metabolism, High-Throughput Nucleotide Sequencing methods, RNA genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Transcription, Genetic

Abstract

RNA biogenesis in eukaryotic cells is a tightly regulated multilayered process in which a diverse set of players act in an orchestrated manner via complex molecular interactions to secure the initial flow of gene expression. Transcription from DNA to RNA is the essential first step in RNA biogenesis, and consists of three main phases: initiation, elongation, and termination. In each phase, transcription factors act on RNA polymerases to modulate their passage along the DNA template in a very precise manner, governed by molecular mechanisms, some of which are not yet fully understood. Genome-scale run-on-based methodologies have been developed with the aim of mapping the position of transcriptionally engaged RNA polymerases. Among them, the BioGRO methodology has been instrumental in advancing our understanding of the transcriptional dynamics in yeast. Here we take the previously known BioGRO method further by coupling it with deep sequencing. BioGRO-seq maps elongating RNA polymerases along the genome with strand specificity and single-nucleotide resolution. BioGRO-seq profiling provides insights into the biogenesis and regulation of not just the canonical protein-coding transcriptome, but also into the often more challenging to study noncoding and unstable transcriptome., (© 2022. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2022

34. SPT5 stabilizes RNA polymerase II, orchestrates transcription cycles, and maintains the enhancer landscape.

Author

Hu S, Peng L, Xu C, Wang Z, Song A, and Chen FX

Subjects

Animals, Antigens, Differentiation, B-Lymphocyte, Chromatin chemistry, Chromatin metabolism, Fibroblasts metabolism, Genome, HEK293 Cells, Histocompatibility Antigens Class II, Humans, Mice, Mutation, Phosphorylation, Promoter Regions, Genetic, RNA-Seq, Regulatory Sequences, Nucleic Acid, Transcriptional Activation, Chromosomal Proteins, Non-Histone metabolism, Enhancer Elements, Genetic, Nuclear Proteins metabolism, RNA Polymerase II metabolism, Transcription, Genetic, Transcriptional Elongation Factors metabolism

Abstract

Transcription progression is governed by multitasking regulators including SPT5, an evolutionarily conserved factor implicated in virtually all transcriptional steps from enhancer activation to termination. Here we utilize a rapid degradation system and reveal crucial functions of SPT5 in maintaining cellular and chromatin RNA polymerase II (Pol II) levels. Rapid SPT5 depletion causes a pronounced reduction of paused Pol II at promoters and enhancers, distinct from negative elongation factor (NELF) degradation resulting in short-distance paused Pol II redistribution. Most genes exhibit downregulation, but not upregulation, accompanied by greatly impaired transcription activation, altered chromatin landscape at enhancers, and severe Pol II processivity defects at gene bodies. Phosphorylation of an SPT5 linker at serine 666 potentiates pause release and is antagonized by Integrator-PP2A (INTAC) targeting SPT5 and Pol II, while phosphorylation of the SPT5 C-terminal region links to 3' end termination. Our findings position SPT5 as an essential positive regulator of global transcription., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2021 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2021

35. FACT is recruited to the +1 nucleosome of transcribed genes and spreads in a Chd1-dependent manner.

Author

Jeronimo C, Angel A, Nguyen VQ, Kim JM, Poitras C, Lambert E, Collin P, Mellor J, Wu C, and Robert F

Subjects

Chromatin metabolism, Chromatin Assembly and Disassembly, Chromosomal Proteins, Non-Histone metabolism, DNA-Binding Proteins genetics, High Mobility Group Proteins genetics, Histone Chaperones genetics, Histones genetics, Histones metabolism, Molecular Chaperones metabolism, Nucleosomes metabolism, Protein Binding, RNA Polymerase II metabolism, Saccharomyces cerevisiae, Saccharomyces cerevisiae Proteins genetics, Transcriptional Elongation Factors genetics, DNA-Binding Proteins metabolism, High Mobility Group Proteins metabolism, Saccharomyces cerevisiae Proteins metabolism, Transcription, Genetic genetics, Transcriptional Elongation Factors metabolism

Abstract

The histone chaperone FACT occupies transcribed regions where it plays prominent roles in maintaining chromatin integrity and preserving epigenetic information. How it is targeted to transcribed regions, however, remains unclear. Proposed models include docking on the RNA polymerase II (RNAPII) C-terminal domain (CTD), recruitment by elongation factors, recognition of modified histone tails, and binding partially disassembled nucleosomes. Here, we systematically test these and other scenarios in Saccharomyces cerevisiae and find that FACT binds transcribed chromatin, not RNAPII. Through a combination of high-resolution genome-wide mapping, single-molecule tracking, and mathematical modeling, we propose that FACT recognizes the +1 nucleosome, as it is partially unwrapped by the engaging RNAPII, and spreads to downstream nucleosomes aided by the chromatin remodeler Chd1. Our work clarifies how FACT interacts with genes, suggests a processive mechanism for FACT function, and provides a framework to further dissect the molecular mechanisms of transcription-coupled histone chaperoning., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

36. Removing quote marks from the RNA polymerase II CTD 'code'.

Author

Dieci G

Subjects

Amino Acid Sequence, Animals, Humans, Protein Domains genetics, Protein Processing, Post-Translational genetics, Histone Code genetics, RNA Polymerase II chemistry, RNA Polymerase II genetics, Tandem Repeat Sequences genetics, Transcription, Genetic genetics

Abstract

In eukaryotes, RNA polymerase II (Pol II) is responsible for the synthesis of all mRNAs and myriads of short and long untranslated RNAs, whose fabrication involves close spatiotemporal coordination between transcription, RNA processing and chromatin modification. Crucial for such a coordination is an unusual C-terminal domain (CTD) of the Pol II largest subunit, made of tandem repetitions (26 in yeast, 52 in chordates) of the heptapeptide with the consensus sequence YSPTSPS. Although largely unstructured and with poor sequence content, the Pol II CTD derives its extraordinary functional versatility from the fact that each amino acid in the heptapeptide can be posttranslationally modified, and that different combinations of CTD covalent marks are specifically recognized by different protein binding partners. These features have led to propose the existence of a Pol II CTD code, but this expression is generally used by authors with some caution, revealed by the frequent use of quote marks for the word 'code'. Based on the theoretical framework of code biology, it is argued here that the Pol II CTD modification system meets the requirements of a true organic code, where different CTD modification states represent organic signs whose organic meanings are biological reactions contributing to the many facets of RNA biogenesis in coordination with RNA synthesis by Pol II. Importantly, the Pol II CTD code is instantiated by adaptor proteins possessing at least two distinct domains, one of which devoted to specific recognition of CTD modification profiles. Furthermore, code rules can be altered by experimental interchange of CTD recognition domains of different adaptor proteins, a fact arguing in favor of the arbitrariness, and thus bona fide character, of the Pol II CTD code. Since the growing family of CTD adaptors includes RNA binding proteins and histone modification complexes, the Pol II CTD code is by its nature integrated with other organic codes, in particular the splicing code and the histone code. These issues will be discussed taking into account fascinating developments in Pol II CTD research, like the discovery of novel modifications at non-consensus sites, the recently recognized CTD physicochemical properties favoring liquid-liquid phase separation, and the discovery that the Pol II CTD, originated before the divergence of most extant eukaryotic taxa, has expanded and diversified with developmental complexity in animals and plants., (Copyright © 2021 Elsevier B.V. All rights reserved.)

Published

2021

37. RNA polymerase II speed: a key player in controlling and adapting transcriptome composition.

Author

Muniz L, Nicolas E, and Trouche D

Subjects

Animals, Biochemistry methods, Gene Expression, Histones genetics, Humans, Molecular Imaging methods, RNA Folding, RNA Polymerase II genetics, RNA Processing, Post-Transcriptional, RNA Splicing, RNA, Messenger genetics, RNA, Messenger metabolism, Chromatin genetics, Chromatin metabolism, RNA Polymerase II chemistry, RNA Polymerase II metabolism, Transcription, Genetic, Transcriptome physiology

Abstract

RNA polymerase II (RNA Pol II) speed or elongation rate, i.e., the number of nucleotides synthesized per unit of time, is a major determinant of transcriptome composition. It controls co-transcriptional processes such as splicing, polyadenylation, and transcription termination, thus regulating the production of alternative splice variants, circular RNAs, alternatively polyadenylated transcripts, or read-through transcripts. RNA Pol II speed itself is regulated in response to intra- and extra-cellular stimuli and can in turn affect the transcriptome composition in response to these stimuli. Evidence points to a potentially important role of transcriptome composition modification through RNA Pol II speed regulation for adaptation of cells to a changing environment, thus pointing to a function of RNA Pol II speed regulation in cellular physiology. Analyzing RNA Pol II speed dynamics may therefore be central to fully understand the regulation of physiological processes, such as the development of multicellular organisms. Recent findings also raise the possibility that RNA Pol II speed deregulation can be detrimental and participate in disease progression. Here, we review initial and current approaches to measure RNA Pol II speed, as well as providing an overview of the factors controlling speed and the co-transcriptional processes which are affected. Finally, we discuss the role of RNA Pol II speed regulation in cell physiology., (©2021 The Authors. Published under the terms of the CC BY NC ND 4.0 license.)

Published

2021

38. Repair of DNA double-strand breaks in RNAPI- and RNAPII-transcribed loci.

Author

Lesage E, Clouaire T, and Legube G

Subjects

Animals, Chromatin metabolism, DNA metabolism, DNA Repair, Humans, RNA Polymerase I metabolism, RNA Polymerase II metabolism, DNA Breaks, Double-Stranded, Recombinational DNA Repair, Transcription, Genetic

Abstract

DNA double-strand breaks (DSBs) are toxic lesions triggered not only by environmental sources, but also by a large number of physiological processes. Of importance, endogenous DSBs frequently occur in genomic loci that are transcriptionally active. Recent work suggests that DSBs occurring in transcribed loci are handled by specific pathway(s) that entail local transcriptional repression, chromatin signaling, the involvement of RNA species and DSB mobility. In this Graphical Review we provide an updated view of the "Transcription-Coupled DSB Repair" (TC-DSBR) pathway(s) that are mounted at DSBs occurring in loci transcribed by RNA Polymerase I (RNAPI) or RNA Polymerase II (RNAPII), highlighting differences and common features, as well as yet unanswered questions., (Copyright © 2021 Elsevier B.V. All rights reserved.)

Published

2021

39. The PP2A-Integrator-CDK9 axis fine-tunes transcription and can be targeted therapeutically in cancer.

Author

Vervoort SJ, Welsh SA, Devlin JR, Barbieri E, Knight DA, Offley S, Bjelosevic S, Costacurta M, Todorovski I, Kearney CJ, Sandow JJ, Fan Z, Blyth B, McLeod V, Vissers JHA, Pavic K, Martin BP, Gregory G, Demosthenous E, Zethoven M, Kong IY, Hawkins ED, Hogg SJ, Kelly MJ, Newbold A, Simpson KJ, Kauko O, Harvey KF, Ohlmeyer M, Westermarck J, Gray N, Gardini A, and Johnstone RW

Subjects

Animals, Cell Line, Tumor, Cyclin-Dependent Kinase 9 antagonists & inhibitors, Drug Resistance, Neoplasm genetics, Gene Expression Regulation, Neoplastic, Humans, Mice, Inbred NOD, Phosphorylation, Protein Binding, RNA Polymerase II chemistry, RNA Polymerase II metabolism, Substrate Specificity, Mice, Cyclin-Dependent Kinase 9 metabolism, Molecular Targeted Therapy, Neoplasms drug therapy, Neoplasms genetics, Protein Phosphatase 2 metabolism, RNA-Binding Proteins metabolism, Transcription, Genetic, Tumor Suppressor Proteins metabolism

Abstract

Gene expression by RNA polymerase II (RNAPII) is tightly controlled by cyclin-dependent kinases (CDKs) at discrete checkpoints during the transcription cycle. The pausing checkpoint following transcription initiation is primarily controlled by CDK9. We discovered that CDK9-mediated, RNAPII-driven transcription is functionally opposed by a protein phosphatase 2A (PP2A) complex that is recruited to transcription sites by the Integrator complex subunit INTS6. PP2A dynamically antagonizes phosphorylation of key CDK9 substrates including DSIF and RNAPII-CTD. Loss of INTS6 results in resistance to tumor cell death mediated by CDK9 inhibition, decreased turnover of CDK9 phospho-substrates, and amplification of acute oncogenic transcriptional responses. Pharmacological PP2A activation synergizes with CDK9 inhibition to kill both leukemic and solid tumor cells, providing therapeutic benefit in vivo. These data demonstrate that fine control of gene expression relies on the balance between kinase and phosphatase activity throughout the transcription cycle, a process dysregulated in cancer that can be exploited therapeutically., Competing Interests: Declaration of interests The Johnstone laboratory receives funding support from Roche, BMS, Astra Zeneca, and MecRx. R.W.J. is a shareholder in MecRx and receives consultancy payments., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

40. Cytoplasmic mRNA decay represses RNA polymerase II transcription during early apoptosis.

Author

Duncan-Lewis C, Hartenian E, King V, and Glaunsinger BA

Subjects

Active Transport, Cell Nucleus, Antineoplastic Agents pharmacology, Cytoplasm genetics, Cytoplasm metabolism, Feedback, Physiological, Gene Expression Regulation, Neoplastic, HCT116 Cells, HEK293 Cells, HeLa Cells, Humans, Neoplasms drug therapy, Neoplasms genetics, Neoplasms pathology, RNA Polymerase II genetics, RNA, Messenger genetics, RNA, Neoplasm genetics, Time Factors, alpha Karyopherins metabolism, beta Karyopherins metabolism, Apoptosis drug effects, Neoplasms metabolism, RNA Polymerase II metabolism, RNA Stability, RNA, Messenger metabolism, RNA, Neoplasm metabolism, Transcription, Genetic

Abstract

RNA abundance is generally sensitive to perturbations in decay and synthesis rates, but crosstalk between RNA polymerase II transcription and cytoplasmic mRNA degradation often leads to compensatory changes in gene expression. Here, we reveal that widespread mRNA decay during early apoptosis represses RNAPII transcription, indicative of positive (rather than compensatory) feedback. This repression requires active cytoplasmic mRNA degradation, which leads to impaired recruitment of components of the transcription preinitiation complex to promoter DNA. Importin α/β-mediated nuclear import is critical for this feedback signaling, suggesting that proteins translocating between the cytoplasm and nucleus connect mRNA decay to transcription. We also show that an analogous pathway activated by viral nucleases similarly depends on nuclear protein import. Collectively, these data demonstrate that accelerated mRNA decay leads to the repression of mRNA transcription, thereby amplifying the shutdown of gene expression. This highlights a conserved gene regulatory mechanism by which cells respond to threats., Competing Interests: CD, EH, VK, BG No competing interests declared, (© 2021, Duncan-Lewis et al.)

Published

2021

41. Promoter G-quadruplex folding precedes transcription and is controlled by chromatin.

Author

Shen J, Varshney D, Simeone A, Zhang X, Adhikari S, Tannahill D, and Balasubramanian S

Subjects

Cell Hypoxia, Cell Line, Tumor, Humans, Models, Genetic, RNA Polymerase II metabolism, Chromatin metabolism, G-Quadruplexes, Promoter Regions, Genetic, Transcription, Genetic

Abstract

Background: Four-stranded G-quadruplexes (G4s) are DNA secondary structures in the human genome that are primarily found in active promoters associated with elevated transcription. Here, we explore the relationship between the folding of promoter G4s, transcription and chromatin state., Results: Transcriptional inhibition by DRB or by triptolide reveals that promoter G4 formation, as assessed by G4 ChIP-seq, does not depend on transcriptional activity. We then show that chromatin compaction can lead to loss of promoter G4s and is accompanied by a corresponding loss of RNA polymerase II (Pol II), thus establishing a link between G4 formation and chromatin accessibility. Furthermore, pre-treatment of cells with a G4-stabilising ligand mitigates the loss of Pol II at promoters induced by chromatin compaction., Conclusions: Overall, our findings show that G4 folding is coupled to the establishment of accessible chromatin and does not require active transcription.

Published

2021

42. POINT technology illuminates the processing of polymerase-associated intact nascent transcripts.

Author

Sousa-Luís R, Dujardin G, Zukher I, Kimura H, Weldon C, Carmo-Fonseca M, Proudfoot NJ, and Nojima T

Subjects

Exoribonucleases genetics, Exoribonucleases metabolism, HCT116 Cells, HeLa Cells, Humans, Kinetics, Polyadenylation, RNA Caps, RNA Polymerase II genetics, RNA Precursors genetics, RNA, Messenger genetics, Nanotechnology, RNA Polymerase II metabolism, RNA Precursors biosynthesis, RNA Splicing, RNA, Messenger biosynthesis, RNA-Seq, Transcription, Genetic

Abstract

Mammalian chromatin is the site of both RNA polymerase II (Pol II) transcription and coupled RNA processing. However, molecular details of such co-transcriptional mechanisms remain obscure, partly because of technical limitations in purifying authentic nascent transcripts. We present a new approach to characterize nascent RNA, called polymerase intact nascent transcript (POINT) technology. This three-pronged methodology maps nascent RNA 5' ends (POINT-5), establishes the kinetics of co-transcriptional splicing patterns (POINT-nano), and profiles whole transcription units (POINT-seq). In particular, we show by depletion of the nuclear exonuclease Xrn2 that this activity acts selectively on cleaved 5' P-RNA at polyadenylation sites. Furthermore, POINT-nano reveals that co-transcriptional splicing either occurs immediately after splice site transcription or is delayed until Pol II transcribes downstream sequences. Finally, we connect RNA cleavage and splicing with either premature or full-length transcript termination. We anticipate that POINT technology will afford full dissection of the complexity of co-transcriptional RNA processing., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2021 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2021

43. ZC3H4 restricts non-coding transcription in human cells.

Author

Estell C, Davidson L, Steketee PC, Monier A, and West S

Subjects

Cell Line, Cell Proliferation, Gene Expression Regulation, Humans, Promoter Regions, Genetic, RNA, Untranslated genetics, RNA-Binding Proteins genetics, Transcription, Genetic

Abstract

The human genome encodes thousands of non-coding RNAs. Many of these terminate early and are then rapidly degraded, but how their transcription is restricted is poorly understood. In a screen for protein-coding gene transcriptional termination factors, we identified ZC3H4. Its depletion causes upregulation and extension of hundreds of unstable transcripts, particularly antisense RNAs and those transcribed from so-called super-enhancers. These loci are occupied by ZC3H4, suggesting that it directly functions in their transcription. Consistently, engineered tethering of ZC3H4 to reporter RNA promotes its degradation by the exosome. ZC3H4 is predominantly metazoan -interesting when considering its impact on enhancer RNAs that are less prominent in single-celled organisms. Finally, ZC3H4 loss causes a substantial reduction in cell proliferation, highlighting its overall importance. In summary, we identify ZC3H4 as playing an important role in restricting non-coding transcription in multicellular organisms., Competing Interests: CE, LD, PS, AM, SW No competing interests declared, (© 2021, Estell et al.)

Published

2021

44. The 7SK/P-TEFb snRNP controls ultraviolet radiation-induced transcriptional reprogramming.

Author

Studniarek C, Tellier M, Martin PGP, Murphy S, Kiss T, and Egloff S

Subjects

CRISPR-Cas Systems, Cell Line, Tumor, Cell Proliferation radiation effects, Cell Survival, Chromatin chemistry, Chromatin metabolism, Chromatin radiation effects, DNA Damage, Gene Deletion, Gene Expression Regulation, Humans, Leukocytes cytology, Leukocytes metabolism, Positive Transcriptional Elongation Factor B metabolism, Promoter Regions, Genetic, Protein Binding, RNA Polymerase II metabolism, RNA-Binding Proteins genetics, RNA-Binding Proteins metabolism, Ribonucleoproteins genetics, Ribonucleoproteins metabolism, Ribonucleoproteins, Small Nuclear deficiency, Stress, Physiological genetics, Transcription Factors genetics, Transcription Factors metabolism, Ultraviolet Rays, Leukocytes radiation effects, Positive Transcriptional Elongation Factor B genetics, RNA Polymerase II genetics, Ribonucleoproteins, Small Nuclear genetics, Transcription, Genetic radiation effects

Abstract

Conversion of promoter-proximally paused RNA polymerase II (RNAPII) into elongating polymerase by the positive transcription elongation factor b (P-TEFb) is a central regulatory step of mRNA synthesis. The activity of P-TEFb is controlled mainly by the 7SK small nuclear ribonucleoprotein (snRNP), which sequesters active P-TEFb into inactive 7SK/P-TEFb snRNP. Here we demonstrate that under normal culture conditions, the lack of 7SK snRNP has only minor impacts on global RNAPII transcription without detectable consequences on cell proliferation. However, upon ultraviolet (UV)-light-induced DNA damage, cells lacking 7SK have a defective transcriptional response and reduced viability. Both UV-induced release of "lesion-scanning" polymerases and activation of key early-responsive genes are compromised in the absence of 7SK. Proper induction of 7SK-dependent UV-responsive genes requires P-TEFb activity directly mobilized from the nucleoplasmic 7SK/P-TEFb snRNP. Our data demonstrate that the primary function of the 7SK/P-TEFb snRNP is to orchestrate the proper transcriptional response to stress., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

45. Ubiquitin-dependent regulation of transcription in development and disease.

Author

Mark KG and Rape M

Subjects

Animals, Histones genetics, Histones metabolism, Humans, RNA Polymerase II genetics, RNA Polymerase II metabolism, Ubiquitination, Transcription, Genetic, Ubiquitin genetics, Ubiquitin metabolism

Abstract

Transcription is an elaborate process that is required to establish and maintain the identity of the more than two hundred cell types of a metazoan organism. Strict regulation of gene expression is therefore vital for tissue formation and homeostasis. An accumulating body of work found that ubiquitylation of histones, transcription factors, or RNA polymerase II is crucial for ensuring that transcription occurs at the right time and place during development. Here, we will review principles of ubiquitin-dependent control of gene expression and discuss how breakdown of these regulatory circuits leads to a wide array of human diseases., (© 2021 The Authors.)

Published

2021

46. Diverse and conserved roles of the protein Ssu72 in eukaryotes: from yeast to higher organisms.

Author

Liu C, Zhang W, and Xing W

Subjects

Amino Acid Sequence genetics, Animals, Humans, Phosphorylation, Saccharomyces cerevisiae genetics, Serine genetics, mRNA Cleavage and Polyadenylation Factors genetics, Phosphoprotein Phosphatases genetics, RNA Polymerase II genetics, Transcription, Genetic

Abstract

Gene transcription is a complex biological process that involves a set of factors, enzymes and nucleotides. Ssu72 plays a crucial role in every step of gene transcription. RNA polymerase II (RNAPII) occupies an important position in the synthesis of mRNAs. The largest subunit of RNAPII, Rpb1, harbors its C-terminal domain (CTD), which participates in the initiation, elongation and termination of transcription. The CTD consists of heptad repeats of the consensus motif Tyr1-Ser2-Pro3-Thr4-Ser5-Pro6-Ser7 and is highly conserved among different species. The CTD is flexible in structure and undergoes conformational changes in response to serine phosphorylation and proline isomerization, which are regulated by specific kinases/phosphatases and isomerases, respectively. Ssu72 is a CTD phosphatase with catalytic activity against phosphorylated Ser5 and Ser7. The isomerization of Pro6 affects the binding of Ssu72 to its substrate. Ssu72 can also indirectly change the phosphorylation status of Ser2. In addition, Ssu72 is a member of the 3'-end cleavage and polyadenylation factor (CPF) complex. Together with other CPF components, Ssu72 regulates the 3'-end processing of premature mRNA. Recent studies have revealed other roles of Ssu72, including its roles in balancing phosphate homeostasis and controlling chromosome behaviors, which should be further explored. In conclusion, the protein Ssu72 is an enzyme worthy of attention, not confined to its role in gene transcription.

Published

2021

47. Stress-induced nuclear condensation of NELF drives transcriptional downregulation.

Author

Rawat P, Boehning M, Hummel B, Aprile-Garcia F, Pandit AS, Eisenhardt N, Khavaran A, Niskanen E, Vos SM, Palvimo JJ, Pichler A, Cramer P, and Sawarkar R

Subjects

Aminoacyltransferases genetics, Aminoacyltransferases metabolism, Chromatin chemistry, Chromatin metabolism, Clone Cells, Cyclin-Dependent Kinase 9 genetics, Cyclin-Dependent Kinase 9 metabolism, Genes, Reporter, HEK293 Cells, HeLa Cells, Humans, Intrinsically Disordered Proteins chemistry, Intrinsically Disordered Proteins metabolism, Luminescent Proteins genetics, Luminescent Proteins metabolism, Phosphorylation, Positive Transcriptional Elongation Factor B genetics, Positive Transcriptional Elongation Factor B metabolism, Promoter Regions, Genetic, RNA Polymerase II metabolism, Signal Transduction, Stress, Physiological, Sumoylation, Transcription Factors genetics, Transcription Factors metabolism, Transcriptional Elongation Factors chemistry, Transcriptional Elongation Factors metabolism, Red Fluorescent Protein, Heat-Shock Response genetics, Intrinsically Disordered Proteins genetics, Protein Processing, Post-Translational, RNA Polymerase II genetics, Transcription, Genetic, Transcriptional Elongation Factors genetics

Abstract

In response to stress, human cells coordinately downregulate transcription and translation of housekeeping genes. To downregulate transcription, the negative elongation factor (NELF) is recruited to gene promoters impairing RNA polymerase II elongation. Here we report that NELF rapidly forms nuclear condensates upon stress in human cells. Condensate formation requires NELF dephosphorylation and SUMOylation induced by stress. The intrinsically disordered region (IDR) in NELFA is necessary for nuclear NELF condensation and can be functionally replaced by the IDR of FUS or EWSR1 protein. We find that biomolecular condensation facilitates enhanced recruitment of NELF to promoters upon stress to drive transcriptional downregulation. Importantly, NELF condensation is required for cellular viability under stressful conditions. We propose that stress-induced NELF condensates reported here are nuclear counterparts of cytosolic stress granules. These two stress-inducible condensates may drive the coordinated downregulation of transcription and translation, likely forming a critical node of the stress survival strategy., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2021 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2021

48. The RNA polymerase II subunit RPB-9 recruits the integrator complex to terminate Caenorhabditis elegans piRNA transcription.

Author

Berkyurek AC, Furlan G, Lampersberger L, Beltran T, Weick EM, Nischwitz E, Cunha Navarro I, Braukmann F, Akay A, Price J, Butter F, Sarkies P, and Miska EA

Subjects

Animals, Caenorhabditis elegans genetics, Caenorhabditis elegans Proteins genetics, Germ Cells, Promoter Regions, Genetic, Protein Subunits, RNA Polymerase II genetics, RNA, Small Interfering genetics, Caenorhabditis elegans metabolism, Caenorhabditis elegans Proteins metabolism, Gene Expression Regulation, Gene Silencing, RNA Polymerase II metabolism, RNA, Small Interfering metabolism, Transcription, Genetic

Abstract

PIWI-interacting RNAs (piRNAs) are genome-encoded small RNAs that regulate germ cell development and maintain germline integrity in many animals. Mature piRNAs engage Piwi Argonaute proteins to silence complementary transcripts, including transposable elements and endogenous genes. piRNA biogenesis mechanisms are diverse and remain poorly understood. Here, we identify the RNA polymerase II (RNA Pol II) core subunit RPB-9 as required for piRNA-mediated silencing in the nematode Caenorhabditis elegans. We show that rpb-9 initiates heritable piRNA-mediated gene silencing at two DNA transposon families and at a subset of somatic genes in the germline. We provide genetic and biochemical evidence that RPB-9 is required for piRNA biogenesis by recruiting the Integrator complex at piRNA genes, hence promoting transcriptional termination. We conclude that, as a part of its rapid evolution, the piRNA pathway has co-opted an ancient machinery for high-fidelity transcription., (© 2021 The Authors. Published under the terms of the CC BY 4.0 license.)

Published

2021

49. Hyperosmotic stress alters the RNA polymerase II interactome and induces readthrough transcription despite widespread transcriptional repression.

Author

Rosa-Mercado NA, Zimmer JT, Apostolidi M, Rinehart J, Simon MD, and Steitz JA

Subjects

Down-Regulation, Endoribonucleases genetics, HEK293 Cells, Humans, RNA genetics, RNA Polymerase II genetics, Time Factors, Endoribonucleases metabolism, Osmotic Pressure, RNA biosynthesis, RNA Polymerase II metabolism, Salt Stress, Transcription, Genetic, Transcriptional Activation

Abstract

Stress-induced readthrough transcription results in the synthesis of downstream-of-gene (DoG)-containing transcripts. The mechanisms underlying DoG formation during cellular stress remain unknown. Nascent transcription profiles during DoG induction in human cell lines using TT-TimeLapse sequencing revealed widespread transcriptional repression upon hyperosmotic stress. Yet, DoGs are produced regardless of the transcriptional level of their upstream genes. ChIP sequencing confirmed that stress-induced redistribution of RNA polymerase (Pol) II correlates with the transcriptional output of genes. Stress-induced alterations in the Pol II interactome are observed by mass spectrometry. While certain cleavage and polyadenylation factors remain Pol II associated, Integrator complex subunits dissociate from Pol II under stress leading to a genome-wide loss of Integrator on DNA. Depleting the catalytic subunit of Integrator using siRNAs induces hundreds of readthrough transcripts, whose parental genes partially overlap those of stress-induced DoGs. Our results provide insights into the mechanisms underlying DoG production and how Integrator activity influences DoG transcription., Competing Interests: Declaration of interests J.A.S. is a member of the Molecular Cell Advisory Board. The authors have no further competing interests to declare., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2021

50. MRE11-RAD50-NBS1 Complex Is Sufficient to Promote Transcription by RNA Polymerase II at Double-Strand Breaks by Melting DNA Ends.

Author

Sharma S, Anand R, Zhang X, Francia S, Michelini F, Galbiati A, Williams H, Ronato DA, Masson JY, Rothenberg E, Cejka P, and d'Adda di Fagagna F

Subjects

Acid Anhydride Hydrolases genetics, Cell Cycle Proteins genetics, DNA Breaks, Double-Stranded, DNA Damage, DNA Repair, DNA-Binding Proteins genetics, HeLa Cells, Humans, MRE11 Homologue Protein genetics, Mutation, Nuclear Proteins genetics, RNA Polymerase II genetics, RNA, Long Noncoding genetics, Recombinant Proteins genetics, Recombinant Proteins metabolism, Acid Anhydride Hydrolases metabolism, Cell Cycle Proteins metabolism, DNA-Binding Proteins metabolism, MRE11 Homologue Protein metabolism, Nuclear Proteins metabolism, Nucleic Acid Denaturation, RNA Polymerase II metabolism, RNA, Long Noncoding biosynthesis, Transcription, Genetic

Abstract

The MRE11-RAD50-NBS1 (MRN) complex supports the synthesis of damage-induced long non-coding RNA (dilncRNA) by RNA polymerase II (RNAPII) from DNA double-strand breaks (DSBs) by an unknown mechanism. Here, we show that recombinant human MRN and native RNAPII are sufficient to reconstitute a minimal functional transcriptional apparatus at DSBs. MRN recruits and stabilizes RNAPII at DSBs. Unexpectedly, transcription is promoted independently from MRN nuclease activities. Rather, transcription depends on the ability of MRN to melt DNA ends, as shown by the use of MRN mutants and specific allosteric inhibitors. Single-molecule FRET assays with wild-type and mutant MRN show a tight correlation between the ability to melt DNA ends and to promote transcription. The addition of RPA enhances MRN-mediated transcription, and unpaired DNA ends allow MRN-independent transcription by RNAPII. These results support a model in which MRN generates single-strand DNA ends that favor the initiation of transcription by RNAPII., Competing Interests: Declaration of Interests The authors declare no competing interests., (Copyright © 2020 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2021