Your search keyword '"RNA Polymerase II metabolism"' showing total 308 results

1. SUN2 mediates calcium-triggered nuclear actin polymerization to cluster active RNA polymerase II.

Author

Ulferts S and Grosse R

Subjects

Humans, Membrane Proteins metabolism, Membrane Proteins genetics, Cell Nucleus metabolism, Animals, Nuclear Envelope metabolism, Nuclear Proteins metabolism, Actin Cytoskeleton metabolism, HeLa Cells, Mice, Intracellular Signaling Peptides and Proteins, RNA Polymerase II metabolism, Calcium metabolism, Actins metabolism, Polymerization

Abstract

The nucleoskeleton is essential for nuclear architecture as well as genome integrity and gene expression. In addition to lamins, titin or spectrins, dynamic actin filament polymerization has emerged as a potential intranuclear structural element but its functions are less well explored. Here we found that calcium elevations trigger rapid nuclear actin assembly requiring the nuclear membrane protein SUN2 independently of its function as a component of the LINC complex. Instead, SUN2 colocalized and associated with the formin and actin nucleator INF2 in the nuclear envelope in a calcium-regulated manner. Moreover, SUN2 is required for active RNA polymerase II (RNA Pol II) clustering in response to calcium elevations. Thus, our data uncover a SUN2-formin module linking the nuclear envelope to intranuclear actin assembly to promote signal-dependent spatial reorganization of active RNA Pol II., (© 2024. The Author(s).)

Published

2024

2. Structural basis of Integrator-dependent RNA polymerase II termination.

Author

Fianu I, Ochmann M, Walshe JL, Dybkov O, Cruz JN, Urlaub H, and Cramer P

Subjects

Transcription Termination, Genetic, Humans, Transcription Factors metabolism, Transcription Factors chemistry, Protein Binding, Transcriptional Elongation Factors metabolism, Transcriptional Elongation Factors chemistry, Nuclear Proteins metabolism, Nuclear Proteins chemistry, Nuclear Proteins ultrastructure, Protein Subunits metabolism, Protein Subunits chemistry, RNA Polymerase II metabolism, RNA Polymerase II chemistry, RNA Polymerase II ultrastructure, Cryoelectron Microscopy, Models, Molecular, Protein Phosphatase 2 metabolism, Protein Phosphatase 2 chemistry, Protein Phosphatase 2 ultrastructure

Abstract

The Integrator complex can terminate RNA polymerase II (Pol II) in the promoter-proximal region of genes. Previous work has shed light on how Integrator binds to the paused elongation complex consisting of Pol II, the DRB sensitivity-inducing factor (DSIF) and the negative elongation factor (NELF) and how it cleaves the nascent RNA transcript 1 , but has not explained how Integrator removes Pol II from the DNA template. Here we present three cryo-electron microscopy structures of the complete Integrator-PP2A complex in different functional states. The structure of the pre-termination complex reveals a previously unresolved, scorpion-tail-shaped INTS10-INTS13-INTS14-INTS15 module that may use its 'sting' to open the DSIF DNA clamp and facilitate termination. The structure of the post-termination complex shows that the previously unresolved subunit INTS3 and associated sensor of single-stranded DNA complex (SOSS) factors prevent Pol II rebinding to Integrator after termination. The structure of the free Integrator-PP2A complex in an inactive closed conformation 2 reveals that INTS6 blocks the PP2A phosphatase active site. These results lead to a model for how Integrator terminates Pol II transcription in three steps that involve major rearrangements., (© 2024. The Author(s).)

Published

2024

3. Structural basis of exoribonuclease-mediated mRNA transcription termination.

Author

Zeng Y, Zhang HW, Wu XX, and Zhang Y

Subjects

Models, Molecular, Protein Binding, RNA-Binding Proteins chemistry, RNA-Binding Proteins metabolism, RNA-Binding Proteins ultrastructure, Transcriptional Elongation Factors chemistry, Transcriptional Elongation Factors metabolism, Transcriptional Elongation Factors ultrastructure, Chromosomal Proteins, Non-Histone chemistry, Chromosomal Proteins, Non-Histone metabolism, Chromosomal Proteins, Non-Histone ultrastructure, Protein Domains, RNA, Fungal biosynthesis, RNA, Fungal chemistry, RNA, Fungal genetics, RNA, Fungal ultrastructure, Cryoelectron Microscopy, Exoribonucleases chemistry, Exoribonucleases metabolism, Exoribonucleases ultrastructure, RNA Polymerase II chemistry, RNA Polymerase II metabolism, RNA Polymerase II ultrastructure, RNA, Messenger biosynthesis, RNA, Messenger chemistry, RNA, Messenger genetics, RNA, Messenger ultrastructure, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae ultrastructure, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins metabolism, Saccharomyces cerevisiae Proteins ultrastructure, Transcription Termination, Genetic

Abstract

Efficient termination is required for robust gene transcription. Eukaryotic organisms use a conserved exoribonuclease-mediated mechanism to terminate the mRNA transcription by RNA polymerase II (Pol II) 1-5 . Here we report two cryogenic electron microscopy structures of Saccharomyces cerevisiae Pol II pre-termination transcription complexes bound to the 5'-to-3' exoribonuclease Rat1 and its partner Rai1. Our structures show that Rat1 displaces the elongation factor Spt5 to dock at the Pol II stalk domain. Rat1 shields the RNA exit channel of Pol II, guides the nascent RNA towards its active centre and stacks three nucleotides at the 5' terminus of the nascent RNA. The structures further show that Rat1 rotates towards Pol II as it shortens RNA. Our results provide the structural mechanism for the Rat1-mediated termination of mRNA transcription by Pol II in yeast and the exoribonuclease-mediated termination of mRNA transcription in other eukaryotes., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

4. Rapid unleashing of macrophage efferocytic capacity via transcriptional pause release.

Author

Tufan T, Comertpay G, Villani A, Nelson GM, Terekhova M, Kelley S, Zakharov P, Ellison RM, Shpynov O, Raymond M, Sun J, Chen Y, Bockelmann E, Stremska M, Peterson LW, Boeckaerts L, Goldman SR, Etchegaray JI, Artyomov MN, Peri F, and Ravichandran KS

Subjects

Animals, Humans, Male, Mice, Apoptosis, Cytoskeleton metabolism, Early Growth Response Protein 3 deficiency, Early Growth Response Protein 3 genetics, Hydrogen-Ion Concentration, Neurons metabolism, Phagosomes metabolism, Transcription Factors genetics, Zebrafish embryology, Zebrafish genetics, Time Factors, Efferocytosis genetics, Macrophages immunology, Macrophages metabolism, RNA Polymerase II metabolism, Transcription Elongation, Genetic

Abstract

During development, inflammation or tissue injury, macrophages may successively engulf and process multiple apoptotic corpses via efferocytosis to achieve tissue homeostasis 1 . How macrophages may rapidly adapt their transcription to achieve continuous corpse uptake is incompletely understood. Transcriptional pause/release is an evolutionarily conserved mechanism, in which RNA polymerase (Pol) II initiates transcription for 20-60 nucleotides, is paused for minutes to hours and is then released to make full-length mRNA 2 . Here we show that macrophages, within minutes of corpse encounter, use transcriptional pause/release to unleash a rapid transcriptional response. For human and mouse macrophages, the Pol II pause/release was required for continuous efferocytosis in vitro and in vivo. Interestingly, blocking Pol II pause/release did not impede Fc receptor-mediated phagocytosis, yeast uptake or bacterial phagocytosis. Integration of data from three genomic approaches-precision nuclear run-on sequencing, RNA sequencing, and assay for transposase-accessible chromatin using sequencing (ATAC-seq)-on efferocytic macrophages at different time points revealed that Pol II pause/release controls expression of select transcription factors and downstream target genes. Mechanistic studies on transcription factor EGR3, prominently regulated by pause/release, uncovered EGR3-related reprogramming of other macrophage genes involved in cytoskeleton and corpse processing. Using lysosomal probes and a new genetic fluorescent reporter, we identify a role for pause/release in phagosome acidification during efferocytosis. Furthermore, microglia from egr3-deficient zebrafish embryos displayed reduced phagocytosis of apoptotic neurons and fewer maturing phagosomes, supporting defective corpse processing. Collectively, these data indicate that macrophages use Pol II pause/release as a mechanism to rapidly alter their transcriptional programs for efficient processing of the ingested apoptotic corpses and for successive efferocytosis., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

5. NELF and PAF1C complexes are core transcriptional machineries controlling colon cancer stemness.

Author

Aoki K, Nitta A, and Igarashi A

Subjects

Humans, Nuclear Proteins genetics, Nuclear Proteins metabolism, RNA Polymerase II metabolism, Transcription, Genetic, Transcriptional Elongation Factors genetics, Transcriptional Elongation Factors metabolism, beta Catenin genetics, beta Catenin metabolism, Colonic Neoplasms genetics, Transcription Factors

Abstract

Mutations in APC, found in 80% of colon caner, enhance β-catenin stabilization, which is the initial step of colonic tumorigenesis. However, the core transcriptional mechanism underlying the induction of colon cancer stemness by stable β-catenin remains unclear. Here, we found that inducible inhibition of β-catenin suppressed elongation of Pol II and RNA polymerase-associated factor 1 complex (PAF1C) around the transcription start site (TSS) of LGR5. Moreover, stable β-catenin enhanced the formation of active Pol II complex cooperatively with CDC73 and CDK9 by facilitating the recruitment of DRB sensitivity-inducing factor (DSIF) and negative elongation factor (NELF) complexes to the Pol II complex. Subsequently, stable β-catenin facilitated the formation of the Pol II-DSIF-PAF1C complex, suggesting that stable β-catenin induces cancer stemness by stimulating active Pol II complex through NELF and PAF1C. Furthermore, NELF or PAF1C inhibition recapitulated the changes in cancer stemness-related gene expression induced by the inhibition of stable β-catenin and suppressed colon cancer stemness. Additionally, the chemical inhibition of CDK12 (a downstream transcription CDK of PAF1C) suppressed colon cancer stemness. These results suggest that NELF and PAF1C are the core transcriptional machineries that control expression of colon cancer stemness-inducing genes and may be therapeutic targets for colon cancer., (© 2024. The Author(s).)

Published

2024

6. Emergence of replication timing during early mammalian development.

Author

Nakatani T, Schauer T, Altamirano-Pacheco L, Klein KN, Ettinger A, Pal M, Gilbert DM, and Torres-Padilla ME

Subjects

Animals, Mice, Blastocyst cytology, Blastocyst metabolism, Chromatin genetics, Epigenome genetics, RNA Polymerase II metabolism, Zygote cytology, Zygote growth & development, Zygote metabolism, DNA Replication Timing, Genome genetics, Embryo, Mammalian cytology, Embryo, Mammalian embryology, Embryo, Mammalian metabolism

Abstract

DNA replication enables genetic inheritance across the kingdoms of life. Replication occurs with a defined temporal order known as the replication timing (RT) programme, leading to organization of the genome into early- or late-replicating regions. RT is cell-type specific, is tightly linked to the three-dimensional nuclear organization of the genome 1,2 and is considered an epigenetic fingerprint 3 . In spite of its importance in maintaining the epigenome 4 , the developmental regulation of RT in mammals in vivo has not been explored. Here, using single-cell Repli-seq 5 , we generated genome-wide RT maps of mouse embryos from the zygote to the blastocyst stage. Our data show that RT is initially not well defined but becomes defined progressively from the 4-cell stage, coinciding with strengthening of the A and B compartments. We show that transcription contributes to the precision of the RT programme and that the difference in RT between the A and B compartments depends on RNA polymerase II at zygotic genome activation. Our data indicate that the establishment of nuclear organization precedes the acquisition of defined RT features and primes the partitioning of the genome into early- and late-replicating domains. Our work sheds light on the establishment of the epigenome at the beginning of mammalian development and reveals the organizing principles of genome organization., (© 2023. The Author(s).)

Published

2024

7. SETD5 regulates the OGT-catalyzed O-GlcNAcylation of RNA polymerase II, which is involved in the stemness of colorectal cancer cells.

Author

Cho HI, Jo S, Kim MS, Kim HB, Liu X, Xuan Y, Cho JW, and Jang YK

Subjects

Humans, Phosphatidylinositol 3-Kinases genetics, Phosphatidylinositol 3-Kinases metabolism, Proto-Oncogene Proteins c-akt metabolism, N-Acetylglucosaminyltransferases metabolism, Catalysis, Protein Processing, Post-Translational, Methyltransferases metabolism, RNA Polymerase II genetics, RNA Polymerase II metabolism, Colorectal Neoplasms genetics

Abstract

The dosage-dependent recruitment of RNA polymerase II (Pol II) at the promoters of genes related to neurodevelopment and stem cell maintenance is required for transcription by the fine-tuned expression of SET-domain-containing protein 5 (SETD5). Pol II O-GlcNAcylation by O-GlcNAc transferase (OGT) is critical for preinitiation complex formation and transcription cycling. SETD5 dysregulation has been linked to stem cell-like properties in some cancer types; however, the role of SETD5 in cancer cell stemness has not yet been determined. We here show that aberrant SETD5 overexpression induces stemness in colorectal cancer (CRC) cells. SETD5 overexpression causes the upregulation of PI3K-AKT pathway-related genes and cancer stem cell (CSC) markers such as CD133, Kruppel-like factor 4 (KLF4), and estrogen-related receptor beta (ESRRB), leading to the gain of stem cell-like phenotypes. Our findings also revealed a functional relationship between SETD5, OGT, and Pol II. OGT-catalyzed Pol II glycosylation depends on SETD5, and the SETD5-Pol II interaction weakens in OGT-depleted cells, suggesting a SETD5-OGT-Pol II interdependence. SETD5 deficiency reduces Pol II occupancy at PI3K-AKT pathway-related genes and CD133 promoters, suggesting a role for SETD5-mediated Pol II recruitment in gene regulation. Moreover, the SETD5 depletion nullified the SETD5-induced stemness of CRC cells and Pol II O-GlcNAcylation. These findings support the hypothesis that SETD5 mediates OGT-catalyzed O-GlcNAcylation of RNA Pol II, which is involved in cancer cell stemness gain via CSC marker gene upregulation., (© 2023. The Author(s).)

Published

2023

8. R-loop-dependent promoter-proximal termination ensures genome stability.

Author

Xu C, Li C, Chen J, Xiong Y, Qiao Z, Fan P, Li C, Ma S, Liu J, Song A, Tao B, Xu T, Xu W, Chi Y, Xue J, Wang P, Ye D, Gu H, Zhang P, Wang Q, Xiao R, Cheng J, Zheng H, Yu X, Zhang Z, Wu J, Liang K, Liu YJ, Lu H, and Chen FX

Subjects

Humans, DNA, Single-Stranded metabolism, DNA-Binding Proteins metabolism, Genome, Human, Mutation, RNA Polymerase II metabolism, Mitochondrial Proteins metabolism, Genomic Instability genetics, Promoter Regions, Genetic genetics, R-Loop Structures genetics, Transcription Termination, Genetic

Abstract

The proper regulation of transcription is essential for maintaining genome integrity and executing other downstream cellular functions 1,2 . Here we identify a stable association between the genome-stability regulator sensor of single-stranded DNA (SOSS) 3 and the transcription regulator Integrator-PP2A (INTAC) 4-6 . Through SSB1-mediated recognition of single-stranded DNA, SOSS-INTAC stimulates promoter-proximal termination of transcription and attenuates R-loops associated with paused RNA polymerase II to prevent R-loop-induced genome instability. SOSS-INTAC-dependent attenuation of R-loops is enhanced by the ability of SSB1 to form liquid-like condensates. Deletion of NABP2 (encoding SSB1) or introduction of cancer-associated mutations into its intrinsically disordered region leads to a pervasive accumulation of R-loops, highlighting a genome surveillance function of SOSS-INTAC that enables timely termination of transcription at promoters to constrain R-loop accumulation and ensure genome stability., (© 2023. The Author(s).)

Published

2023

9. Hydroxyurea and inactivation of checkpoint kinase MEC1 inhibit transcription termination and pre-mRNA cleavage at polyadenylation sites in budding yeast.

Author

Kaur P, Nagar S, Mehta R, Sahadeo K, and Vancura A

Subjects

Checkpoint Kinase 2 metabolism, Hydroxyurea pharmacology, Polyadenylation, RNA Polymerase II metabolism, RNA Precursors genetics, RNA Precursors metabolism, RNA, Messenger genetics, RNA, Messenger metabolism, Transcription, Genetic, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Saccharomycetales genetics

Abstract

The DNA damage response (DDR) is an evolutionarily conserved process essential for cell survival. The transcription changes triggered by DDR depend on the nature of DNA damage, activation of checkpoint kinases, and the stage of cell cycle. The transcription changes can be localized and affect only damaged DNA, but they can be also global and affect genes that are not damaged. While the purpose of localized transcription inhibition is to avoid transcription of damaged genes and make DNA accessible for repair, the purpose and mechanisms of global transcription inhibition of undamaged genes are less well understood. We show here that a brief cell treatment with hydroxyurea (HU) globally inhibits RNA synthesis and transcription by RNA polymerase I, II, and III (RNAPI, RNAPII, and RNAPIII). HU reduces efficiency of transcription termination and inhibits pre-mRNA cleavage at the polyadenylation (pA) sites, destabilizes mRNAs, and shortens poly(A) tails of mRNAs, indicating defects in pre-mRNA 3' end processing. Inactivation of the checkpoint kinase Mec1p downregulates the efficiency of transcription termination and reduces the efficiency of pre-mRNAs clevage at the pA sites, suggesting the involvement of DNA damage checkpoint in transcription termination and pre-mRNA 3' end processing., (© 2023. Springer Nature Limited.)

Published

2023

10. OBOX regulates mouse zygotic genome activation and early development.

Author

Ji S, Chen F, Stein P, Wang J, Zhou Z, Wang L, Zhao Q, Lin Z, Liu B, Xu K, Lai F, Xiong Z, Hu X, Kong T, Kong F, Huang B, Wang Q, Xu Q, Fan Q, Liu L, Williams CJ, Schultz RM, and Xie W

Subjects

Animals, Mice, Chromatin genetics, Chromatin metabolism, Enhancer Elements, Genetic genetics, Mouse Embryonic Stem Cells metabolism, Mutation, Promoter Regions, Genetic genetics, RNA Polymerase II metabolism, Embryonic Development genetics, Gene Expression Regulation, Developmental, Genome genetics, Homeodomain Proteins genetics, Homeodomain Proteins metabolism, Transcription Factors deficiency, Transcription Factors genetics, Transcription Factors metabolism, Zygote metabolism

Abstract

Zygotic genome activation (ZGA) activates the quiescent genome to enable the maternal-to-zygotic transition 1,2 . However, the identity of transcription factors that underlie mammalian ZGA in vivo remains elusive. Here we show that OBOX, a PRD-like homeobox domain transcription factor family (OBOX1-OBOX8) 3-5 , are key regulators of mouse ZGA. Mice deficient for maternally transcribed Obox1/2/5/7 and zygotically expressed Obox3/4 had a two-cell to four-cell arrest, accompanied by impaired ZGA. The Obox knockout defects could be rescued by restoring either maternal and zygotic OBOX, which suggests that maternal and zygotic OBOX redundantly support embryonic development. Chromatin-binding analysis showed that Obox knockout preferentially affected OBOX-binding targets. Mechanistically, OBOX facilitated the 'preconfiguration' of RNA polymerase II, as the polymerase relocated from the initial one-cell binding targets to ZGA gene promoters and distal enhancers. Impaired polymerase II preconfiguration in Obox mutants was accompanied by defective ZGA and chromatin accessibility transition, as well as aberrant activation of one-cell polymerase II targets. Finally, ectopic expression of OBOX activated ZGA genes and MERVL repeats in mouse embryonic stem cells. These data thus demonstrate that OBOX regulates mouse ZGA and early embryogenesis., (© 2023. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2023

11. RNA polymerase II associates with active genes during DNA replication.

Author

Fenstermaker TK, Petruk S, Kovermann SK, Brock HW, and Mazo A

Subjects

DNA Polymerase II metabolism, Epigenesis, Genetic, Proliferating Cell Nuclear Antigen metabolism, Transcription Factors, General metabolism, RNA genetics, RNA metabolism, Chromatin genetics, DNA biosynthesis, DNA genetics, DNA metabolism, DNA Replication, Genes, RNA Polymerase II metabolism, Transcription, Genetic

Abstract

The transcriptional machinery is thought to dissociate from DNA during replication. Certain proteins, termed epigenetic marks, must be transferred from parent to daughter DNA strands in order to maintain the memory of transcriptional states 1,2 . These proteins are believed to re-initiate rebuilding of chromatin structure, which ultimately recruits RNA polymerase II (Pol II) to the newly replicated daughter strands. It is believed that Pol II is recruited back to active genes only after chromatin is rebuilt 3,4 . However, there is little experimental evidence addressing the central questions of when and how Pol II is recruited back to the daughter strands and resumes transcription. Here we show that immediately after passage of the replication fork, Pol II in complex with other general transcription proteins and immature RNA re-associates with active genes on both leading and lagging strands of nascent DNA, and rapidly resumes transcription. This suggests that the transcriptionally active Pol II complex is retained in close proximity to DNA, with a Pol II-PCNA interaction potentially underlying this retention. These findings indicate that the Pol II machinery may not require epigenetic marks to be recruited to the newly synthesized DNA during the transition from DNA replication to resumption of transcription., (© 2023. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2023

12. Structure of the SNAPc-bound RNA polymerase III preinitiation complex.

Author

Hou H, Jin Q, Ren Y, Chen Z, Wang Q, and Xu Y

Subjects

DNA-Binding Proteins metabolism, RNA Polymerase II metabolism, Transcription, Genetic, RNA, Small Nuclear, RNA Polymerase III genetics, Transcription Factors genetics

Published

2023

13. Formin-mediated nuclear actin at androgen receptors promotes transcription.

Author

Knerr J, Werner R, Schwan C, Wang H, Gebhardt P, Grötsch H, Caliebe A, Spielmann M, Holterhus PM, Grosse R, and Hornig NC

Subjects

Humans, Androgen-Insensitivity Syndrome genetics, Androgen-Insensitivity Syndrome metabolism, Androgens pharmacology, Androgens metabolism, Gene Expression Regulation drug effects, Polymerization drug effects, Prostate-Specific Antigen metabolism, Prostatic Neoplasms genetics, Prostatic Neoplasms metabolism, Prostatic Neoplasms pathology, RNA Polymerase II metabolism, Signal Transduction drug effects, Steroids metabolism, Steroids pharmacology, Testosterone analogs & derivatives, Actins metabolism, Formins metabolism, Nuclear Proteins metabolism, Receptors, Androgen metabolism, Transcription, Genetic drug effects

Abstract

Steroid hormone receptors are ligand-binding transcription factors essential for mammalian physiology. The androgen receptor (AR) binds androgens mediating gene expression for sexual, somatic and behavioural functions, and is involved in various conditions including androgen insensitivity syndrome and prostate cancer 1 . Here we identified functional mutations in the formin and actin nucleator DAAM2 in patients with androgen insensitivity syndrome. DAAM2 was enriched in the nucleus, where its localization correlated with that of the AR to form actin-dependent transcriptional droplets in response to dihydrotestosterone. DAAM2 AR droplets ranged from 0.02 to 0.06 µm 3 in size and associated with active RNA polymerase II. DAAM2 polymerized actin directly at the AR to promote droplet coalescence in a highly dynamic manner, and nuclear actin polymerization is required for prostate-specific antigen expression in cancer cells. Our data uncover signal-regulated nuclear actin assembly at a steroid hormone receptor necessary for transcription., (© 2023. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2023

14. H3K4me2/3 modulate the stability of RNA polymerase II pausing.

Author

Hu S, Song A, Peng L, Tang N, Qiao Z, Wang Z, Lan F, and Chen FX

Subjects

Promoter Regions, Genetic, DNA-Directed RNA Polymerases genetics, RNA Polymerase II metabolism, Transcription, Genetic

Published

2023

15. Ageing-associated changes in transcriptional elongation influence longevity.

Author

Debès C, Papadakis A, Grönke S, Karalay Ö, Tain LS, Mizi A, Nakamura S, Hahn O, Weigelt C, Josipovic N, Zirkel A, Brusius I, Sofiadis K, Lamprousi M, Lu YX, Huang W, Esmaillie R, Kubacki T, Späth MR, Schermer B, Benzing T, Müller RU, Antebi A, Partridge L, Papantonis A, and Beyer A

Subjects

Animals, Humans, Mice, Rats, Insulin metabolism, RNA Polymerase II genetics, RNA Polymerase II metabolism, Signal Transduction, Drosophila melanogaster genetics, Caenorhabditis elegans genetics, RNA, Circular, Somatomedins, Nucleosomes, Histones, Cell Division, Caloric Restriction, Aging genetics, Longevity genetics, Transcription Elongation, Genetic

Abstract

Physiological homeostasis becomes compromised during ageing, as a result of impairment of cellular processes, including transcription and RNA splicing 1-4 . However, the molecular mechanisms leading to the loss of transcriptional fidelity are so far elusive, as are ways of preventing it. Here we profiled and analysed genome-wide, ageing-related changes in transcriptional processes across different organisms: nematodes, fruitflies, mice, rats and humans. The average transcriptional elongation speed (RNA polymerase II speed) increased with age in all five species. Along with these changes in elongation speed, we observed changes in splicing, including a reduction of unspliced transcripts and the formation of more circular RNAs. Two lifespan-extending interventions, dietary restriction and lowered insulin-IGF signalling, both reversed most of these ageing-related changes. Genetic variants in RNA polymerase II that reduced its speed in worms 5 and flies 6 increased their lifespan. Similarly, reducing the speed of RNA polymerase II by overexpressing histone components, to counter age-associated changes in nucleosome positioning, also extended lifespan in flies and the division potential of human cells. Our findings uncover fundamental molecular mechanisms underlying animal ageing and lifespan-extending interventions, and point to possible preventive measures., (© 2023. The Author(s).)

Published

2023

16. H3K4me3 regulates RNA polymerase II promoter-proximal pause-release.

Author

Wang H, Fan Z, Shliaha PV, Miele M, Hendrickson RC, Jiang X, and Helin K

Subjects

Animals, Mice, Gene Expression Regulation, Histone Demethylases metabolism, Methylation, Histones chemistry, Histones metabolism, Mouse Embryonic Stem Cells metabolism, Promoter Regions, Genetic genetics, RNA Polymerase II metabolism, Transcription Elongation, Genetic, Transcription Termination, Genetic

Abstract

Trimethylation of histone H3 lysine 4 (H3K4me3) is associated with transcriptional start sites and has been proposed to regulate transcription initiation 1,2 . However, redundant functions of the H3K4 SET1/COMPASS methyltransferase complexes complicate the elucidation of the specific role of H3K4me3 in transcriptional regulation 3,4 . Here, using mouse embryonic stem cells as a model system, we show that acute ablation of shared subunits of the SET1/COMPASS complexes leads to a complete loss of all H3K4 methylation. Turnover of H3K4me3 occurs more rapidly than that of H3K4me1 and H3K4me2 and is dependent on KDM5 demethylases. Notably, acute loss of H3K4me3 does not have detectable effects on transcriptional initiation but leads to a widespread decrease in transcriptional output, an increase in RNA polymerase II (RNAPII) pausing and slower elongation. We show that H3K4me3 is required for the recruitment of the integrator complex subunit 11 (INTS11), which is essential for the eviction of paused RNAPII and transcriptional elongation. Thus, our study demonstrates a distinct role for H3K4me3 in transcriptional pause-release and elongation rather than transcriptional initiation., (© 2023. The Author(s).)

Published

2023

17. MYC multimers shield stalled replication forks from RNA polymerase.

Author

Solvie D, Baluapuri A, Uhl L, Fleischhauer D, Endres T, Papadopoulos D, Aziba A, Gaballa A, Mikicic I, Isaakova E, Giansanti C, Jansen J, Jungblut M, Klein T, Schülein-Völk C, Maric H, Doose S, Sauer M, Beli P, Rosenwald A, Dobbelstein M, Wolf E, and Eilers M

Subjects

Humans, Chromatin genetics, Promoter Regions, Genetic genetics, RNA Polymerase II metabolism, Transcription, Genetic, Tumor Suppressor Proteins metabolism, Ubiquitin-Protein Ligases metabolism, DNA Breaks, Double-Stranded, S Phase, Binding Sites, RNA, Messenger biosynthesis, DNA-Directed RNA Polymerases metabolism

Abstract

Oncoproteins of the MYC family drive the development of numerous human tumours 1 . In unperturbed cells, MYC proteins bind to nearly all active promoters and control transcription by RNA polymerase II 2,3 . MYC proteins can also coordinate transcription with DNA replication 4,5 and promote the repair of transcription-associated DNA damage 6 , but how they exert these mechanistically diverse functions is unknown. Here we show that MYC dissociates from many of its binding sites in active promoters and forms multimeric, often sphere-like structures in response to perturbation of transcription elongation, mRNA splicing or inhibition of the proteasome. Multimerization is accompanied by a global change in the MYC interactome towards proteins involved in transcription termination and RNA processing. MYC multimers accumulate on chromatin immediately adjacent to stalled replication forks and surround FANCD2, ATR and BRCA1 proteins, which are located at stalled forks 7,8 . MYC multimerization is triggered in a HUWE1 6 and ubiquitylation-dependent manner. At active promoters, MYC multimers block antisense transcription and stabilize FANCD2 association with chromatin. This limits DNA double strand break formation during S-phase, suggesting that the multimerization of MYC enables tumour cells to proliferate under stressful conditions., (© 2022. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2022

18. Single molecule microscopy to profile the effect of zinc status on transcription factor dynamics.

Author

Damon LJ, Aaron J, and Palmer AE

Subjects

CCCTC-Binding Factor genetics, Zinc metabolism, Single Molecule Imaging, RNA Polymerase II metabolism, Chromatin, DNA chemistry, Transcription Factors genetics, Transcription Factors metabolism, Receptors, Glucocorticoid genetics, Receptors, Glucocorticoid metabolism

Abstract

The regulation of transcription is a complex process that involves binding of transcription factors (TFs) to specific sequences, recruitment of cofactors and chromatin remodelers, assembly of the pre-initiation complex and recruitment of RNA polymerase II. Increasing evidence suggests that TFs are highly dynamic and interact only transiently with DNA. Single molecule microscopy techniques are powerful approaches for tracking individual TF molecules as they diffuse in the nucleus and interact with DNA. Here we employ multifocus microscopy and highly inclined laminated optical sheet microscopy to track TF dynamics in response to perturbations in labile zinc inside cells. We sought to define whether zinc-dependent TFs sense changes in the labile zinc pool by determining whether their dynamics and DNA binding can be modulated by zinc. We used fluorescently tagged versions of the glucocorticoid receptor (GR), with two C4 zinc finger domains, and CCCTC-binding factor (CTCF), with eleven C2H2 zinc finger domains. We found that GR was largely insensitive to perturbations of zinc, whereas CTCF was significantly affected by zinc depletion and its dwell time was affected by zinc elevation. These results indicate that at least some transcription factors are sensitive to zinc dynamics, revealing a potential new layer of transcriptional regulation., (© 2022. The Author(s).)

Published

2022

19. A mechanism for oxidative damage repair at gene regulatory elements.

Author

Ray S, Abugable AA, Parker J, Liversidge K, Palminha NM, Liao C, Acosta-Martin AE, Souza CDS, Jurga M, Sudbery I, and El-Khamisy SF

Subjects

Chromatin genetics, Genes, Genetic Complementation Test, Mitosis, Mutation, Phosphoric Diester Hydrolases metabolism, Poly ADP Ribosylation, RNA biosynthesis, RNA genetics, RNA Polymerase II metabolism, Spindle Apparatus metabolism, Transcription Initiation Site, Cell Cycle Proteins metabolism, DNA Damage, DNA Repair, Oxidative Stress genetics, Promoter Regions, Genetic genetics

Abstract

Oxidative genome damage is an unavoidable consequence of cellular metabolism. It arises at gene regulatory elements by epigenetic demethylation during transcriptional activation 1,2 . Here we show that promoters are protected from oxidative damage via a process mediated by the nuclear mitotic apparatus protein NuMA (also known as NUMA1). NuMA exhibits genomic occupancy approximately 100 bp around transcription start sites. It binds the initiating form of RNA polymerase II, pause-release factors and single-strand break repair (SSBR) components such as TDP1. The binding is increased on chromatin following oxidative damage, and TDP1 enrichment at damaged chromatin is facilitated by NuMA. Depletion of NuMA increases oxidative damage at promoters. NuMA promotes transcription by limiting the polyADP-ribosylation of RNA polymerase II, increasing its availability and release from pausing at promoters. Metabolic labelling of nascent RNA identifies genes that depend on NuMA for transcription including immediate-early response genes. Complementation of NuMA-deficient cells with a mutant that mediates binding to SSBR, or a mitotic separation-of-function mutant, restores SSBR defects. These findings underscore the importance of oxidative DNA damage repair at gene regulatory elements and describe a process that fulfils this function., (© 2022. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2022

20. Structural basis of human transcription-DNA repair coupling.

Author

Kokic G, Wagner FR, Chernev A, Urlaub H, and Cramer P

Subjects

Carrier Proteins chemistry, Carrier Proteins metabolism, Carrier Proteins ultrastructure, DNA Helicases chemistry, DNA Helicases metabolism, DNA Helicases ultrastructure, DNA Repair Enzymes chemistry, DNA Repair Enzymes metabolism, DNA Repair Enzymes ultrastructure, DNA-Binding Proteins chemistry, DNA-Binding Proteins metabolism, DNA-Binding Proteins ultrastructure, Humans, Models, Molecular, Multiprotein Complexes metabolism, Poly-ADP-Ribose Binding Proteins chemistry, Poly-ADP-Ribose Binding Proteins metabolism, Poly-ADP-Ribose Binding Proteins ultrastructure, RNA Polymerase II metabolism, Transcription Elongation, Genetic, Transcription Factor TFIIH chemistry, Transcription Factor TFIIH metabolism, Transcription Factor TFIIH ultrastructure, Transcription Factors chemistry, Transcription Factors metabolism, Transcription Factors ultrastructure, Ubiquitin-Protein Ligases chemistry, Ubiquitin-Protein Ligases metabolism, Ubiquitin-Protein Ligases ultrastructure, Ubiquitination, Cryoelectron Microscopy, DNA Repair, Multiprotein Complexes chemistry, Multiprotein Complexes ultrastructure, RNA Polymerase II chemistry, RNA Polymerase II ultrastructure, Transcription, Genetic

Abstract

Transcription-coupled DNA repair removes bulky DNA lesions from the genome 1,2 and protects cells against ultraviolet (UV) irradiation 3 . Transcription-coupled DNA repair begins when RNA polymerase II (Pol II) stalls at a DNA lesion and recruits the Cockayne syndrome protein CSB, the E3 ubiquitin ligase, CRL4 CSA and UV-stimulated scaffold protein A (UVSSA) 3 . Here we provide five high-resolution structures of Pol II transcription complexes containing human transcription-coupled DNA repair factors and the elongation factors PAF1 complex (PAF) and SPT6. Together with biochemical and published 3,4 data, the structures provide a model for transcription-repair coupling. Stalling of Pol II at a DNA lesion triggers replacement of the elongation factor DSIF by CSB, which binds to PAF and moves upstream DNA to SPT6. The resulting elongation complex, EC TCR , uses the CSA-stimulated translocase activity of CSB to pull on upstream DNA and push Pol II forward. If the lesion cannot be bypassed, CRL4 CSA spans over the Pol II clamp and ubiquitylates the RPB1 residue K1268, enabling recruitment of TFIIH to UVSSA and DNA repair. Conformational changes in CRL4 CSA lead to ubiquitylation of CSB and to release of transcription-coupled DNA repair factors before transcription may continue over repaired DNA., (© 2021. The Author(s).)

Published

2021

21. Joint changes in RNA, RNA polymerase II, and promoter activity through the cell cycle identify non-coding RNAs involved in proliferation.

Author

Hegre SA, Samdal H, Klima A, Stovner EB, Nørsett KG, Liabakk NB, Olsen LC, Chawla K, Aas PA, and Sætrom P

Subjects

Chromatin Immunoprecipitation Sequencing, Gene Knockdown Techniques, HaCaT Cells, Humans, Promoter Regions, Genetic, RNA, Long Noncoding genetics, RNA-Seq, Cell Cycle genetics, Cell Proliferation genetics, RNA Polymerase II metabolism, RNA, Long Noncoding metabolism

Abstract

Proper regulation of the cell cycle is necessary for normal growth and development of all organisms. Conversely, altered cell cycle regulation often underlies proliferative diseases such as cancer. Long non-coding RNAs (lncRNAs) are recognized as important regulators of gene expression and are often found dysregulated in diseases, including cancers. However, identifying lncRNAs with cell cycle functions is challenging due to their often low and cell-type specific expression. We present a highly effective method that analyses changes in promoter activity, transcription, and RNA levels for identifying genes enriched for cell cycle functions. Specifically, by combining RNA sequencing with ChIP sequencing through the cell cycle of synchronized human keratinocytes, we identified 1009 genes with cell cycle-dependent expression and correlated changes in RNA polymerase II occupancy or promoter activity as measured by histone 3 lysine 4 trimethylation (H3K4me3). These genes were highly enriched for genes with known cell cycle functions and included 57 lncRNAs. We selected four of these lncRNAs-SNHG26, EMSLR, ZFAS1, and EPB41L4A-AS1-for further experimental validation and found that knockdown of each of the four lncRNAs affected cell cycle phase distributions and reduced proliferation in multiple cell lines. These results show that many genes with cell cycle functions have concomitant cell-cycle dependent changes in promoter activity, transcription, and RNA levels and support that our multi-omics method is well suited for identifying lncRNAs involved in the cell cycle., (© 2021. The Author(s).)

Published

2021

22. Histone H2Bub1 deubiquitylation is essential for mouse development, but does not regulate global RNA polymerase II transcription.

Author

Wang F, El-Saafin F, Ye T, Stierle M, Negroni L, Durik M, Fischer V, Devys D, Vincent SD, and Tora L

Subjects

Animals, Mice, Transcription Factors metabolism, Ubiquitination, Gene Expression genetics, Histones metabolism, RNA Polymerase II genetics, RNA Polymerase II metabolism

Abstract

Co-activator complexes dynamically deposit post-translational modifications (PTMs) on histones, or remove them, to regulate chromatin accessibility and/or to create/erase docking surfaces for proteins that recognize histone PTMs. SAGA (Spt-Ada-Gcn5 Acetyltransferase) is an evolutionary conserved multisubunit co-activator complex with modular organization. The deubiquitylation module (DUB) of mammalian SAGA complex is composed of the ubiquitin-specific protease 22 (USP22) and three adaptor proteins, ATXN7, ATXN7L3 and ENY2, which are all needed for the full activity of the USP22 enzyme to remove monoubiquitin (ub1) from histone H2B. Two additional USP22-related ubiquitin hydrolases (called USP27X or USP51) have been described to form alternative DUBs with ATXN7L3 and ENY2, which can also deubiquitylate H2Bub1. Here we report that USP22 and ATXN7L3 are essential for normal embryonic development of mice, however their requirements are not identical during this process, as Atxn7l3 -/- embryos show developmental delay already at embryonic day (E) 7.5, while Usp22 -/- embryos are normal at this stage, but die at E14.5. Global histone H2Bub1 levels were only slightly affected in Usp22 null embryos, in contrast H2Bub1 levels were strongly increased in Atxn7l3 null embryos and derived cell lines. Our transcriptomic analyses carried out from wild type and Atxn7l3 -/- mouse embryonic stem cells (mESCs), or primary mouse embryonic fibroblasts (MEFs) suggest that the ATXN7L3-related DUB activity regulates only a subset of genes in both cell types. However, the gene sets and the extent of their deregulation were different in mESCs and MEFs. Interestingly, the strong increase of H2Bub1 levels observed in the Atxn7l3 -/- mESCs, or Atxn7l3 -/- MEFs, does not correlate with the modest changes in RNA Polymerase II (Pol II) occupancy and lack of changes in Pol II elongation observed in the two Atxn7l3 -/- cellular systems. These observations together indicate that deubiquitylation of histone H2Bub1 does not directly regulate global Pol II transcription elongation., (© 2021. The Author(s).)

Published

2021

23. Shape of promoter antisense RNAs regulates ligand-induced transcription activation.

Author

Yang F, Tanasa B, Micheletti R, Ohgi KA, Aggarwal AK, and Rosenfeld MG

Subjects

Cell Line, Chromobox Protein Homolog 5 metabolism, Crk-Associated Substrate Protein, Estrogen Receptor alpha metabolism, Histones chemistry, Histones metabolism, Humans, Jumonji Domain-Containing Histone Demethylases metabolism, Ligands, Positive Transcriptional Elongation Factor B metabolism, RNA Polymerase II metabolism, RNA Stability, Tripartite Motif-Containing Protein 28 metabolism, Nucleic Acid Conformation, Promoter Regions, Genetic genetics, RNA, Antisense chemistry, RNA, Antisense genetics, Transcriptional Activation genetics

Abstract

The size of the transcriptional program of long non-coding RNAs in the mammalian genome has engendered discussions about their biological roles 1 , particularly the promoter antisense (PAS) transcripts 2,3 . Here we report the development of an assay-referred to as chromatin isolation by RNA-Cas13a complex-to quantitatively detect the distribution of RNA in the genome. The assay revealed that PAS RNAs serve as a key gatekeeper of a broad transcriptional pause release program, based on decommissioning the 7SK small nuclear RNA-dependent inhibitory P-TEFb complex. Induction of PAS RNAs by liganded ERα led to a significant loss of H3K9me3 and the release of basally recruited HP1α and KAP1 on activated target gene promoters. This release was due to PAS RNA-dependent recruitment of H3K9me3 demethylases, which required interactions with a compact stem-loop structure in the PAS RNAs, an apparent feature of similarly regulated PAS RNAs. Activation of the ERα-bound MegaTrans enhancer, which is essential for robust pause release, required the recruitment of phosphorylated KAP1, with its transfer to the cognate promoters permitting 17β-oestradiol-induced pause release and activation of the target gene. This study reveals a mechanism, based on RNA structure, that mediates the function of PAS RNAs in gene regulation., (© 2021. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2021

24. Constrained G4 structures unveil topology specificity of known and new G4 binding proteins.

Author

Pipier A, Devaux A, Lavergne T, Adrait A, Couté Y, Britton S, Calsou P, Riou JF, Defrancq E, and Gomez D

Subjects

DNA-Binding Proteins metabolism, HeLa Cells, Humans, RNA Polymerase II chemistry, RNA Polymerase II metabolism, Transcription Factors chemistry, DNA-Binding Proteins chemistry, G-Quadruplexes, Oligonucleotides chemistry, Transcription Factors metabolism

Abstract

G-quadruplexes (G4) are non-canonical secondary structures consisting in stacked tetrads of hydrogen-bonded guanines bases. An essential feature of G4 is their intrinsic polymorphic nature, which is characterized by the equilibrium between several conformations (also called topologies) and the presence of different types of loops with variable lengths. In cells, G4 functions rely on protein or enzymatic factors that recognize and promote or resolve these structures. In order to characterize new G4-dependent mechanisms, extensive researches aimed at identifying new G4 binding proteins. Using G-rich single-stranded oligonucleotides that adopt non-controlled G4 conformations, a large number of G4-binding proteins have been identified in vitro, but their specificity towards G4 topology remained unknown. Constrained G4 structures are biomolecular objects based on the use of a rigid cyclic peptide scaffold as a template for directing the intramolecular assembly of the anchored oligonucleotides into a single and stabilized G4 topology. Here, using various constrained RNA or DNA G4 as baits in human cell extracts, we establish the topology preference of several well-known G4-interacting factors. Moreover, we identify new G4-interacting proteins such as the NELF complex involved in the RNA-Pol II pausing mechanism, and we show that it impacts the clastogenic effect of the G4-ligand pyridostatin.

Published

2021

25. Structures of mammalian RNA polymerase II pre-initiation complexes.

Author

Aibara S, Schilbach S, and Cramer P

Subjects

Animals, Base Pairing, DNA genetics, DNA Helicases metabolism, DNA-Binding Proteins metabolism, Humans, Mammals genetics, Models, Molecular, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae genetics, TATA Box genetics, Transcription Factor TFIIH chemistry, Transcription Factor TFIIH metabolism, Transcription Initiation Site, Transcription Initiation, Genetic, DNA chemistry, DNA metabolism, Promoter Regions, Genetic genetics, RNA Polymerase II chemistry, RNA Polymerase II metabolism

Abstract

The initiation of transcription is a focal point for the regulation of gene activity during mammalian cell differentiation and development. To initiate transcription, RNA polymerase II (Pol II) assembles with general transcription factors into a pre-initiation complex (PIC) that opens promoter DNA. Previous work provided the molecular architecture of the yeast 1-9 and human 10,11 PIC and a topological model for DNA opening by the general transcription factor TFIIH 12-14 . Here we report the high-resolution cryo-electron microscopy structure of PIC comprising human general factors and Sus scrofa domesticus Pol II, which is 99.9% identical to human Pol II. We determine the structures of PIC with closed and opened promoter DNA at 2.5-2.8 Å resolution, and resolve the structure of TFIIH at 2.9-4.0 Å resolution. We capture the TFIIH translocase XPB in the pre- and post-translocation states, and show that XPB induces and propagates a DNA twist to initiate the opening of DNA approximately 30 base pairs downstream of the TATA box. We also provide evidence that DNA opening occurs in two steps and leads to the detachment of TFIIH from the core PIC, which may stop DNA twisting and enable RNA chain initiation.

Published

2021

26. A phase-separated nuclear GBPL circuit controls immunity in plants.

Author

Huang S, Zhu S, Kumar P, and MacMicking JD

Subjects

Arabidopsis genetics, Arabidopsis metabolism, Arabidopsis ultrastructure, Cell Nucleus genetics, Cell Nucleus ultrastructure, Chromatin genetics, Cryoelectron Microscopy, GTP-Binding Proteins chemistry, GTP-Binding Proteins ultrastructure, Gene Expression Regulation, Plant genetics, Intrinsically Disordered Proteins chemistry, Intrinsically Disordered Proteins ultrastructure, Mediator Complex, Multigene Family genetics, Organelles chemistry, Organelles immunology, Organelles metabolism, Organelles ultrastructure, Plant Cells chemistry, Plant Cells immunology, Plant Cells metabolism, Plant Cells ultrastructure, Plant Diseases immunology, Promoter Regions, Genetic genetics, RNA Polymerase II metabolism, Transcription, Genetic, Arabidopsis immunology, Cell Nucleus chemistry, Cell Nucleus metabolism, GTP-Binding Proteins metabolism, Intrinsically Disordered Proteins metabolism, Phase Transition, Plant Immunity genetics

Abstract

Liquid-liquid phase separation (LLPS) has emerged as a central paradigm for understanding how membraneless organelles compartmentalize diverse cellular activities in eukaryotes 1-3 . Here we identify a superfamily of plant guanylate-binding protein (GBP)-like GTPases (GBPLs) that assemble LLPS-driven condensates within the nucleus to protect against infection and autoimmunity. In Arabidopsis thaliana, two members of this family-GBPL1 and GBPL3-undergo phase-transition behaviour to control transcriptional responses as part of an allosteric switch that is triggered by exposure to biotic stress. GBPL1, a pseudo-GTPase, sequesters catalytically active GBPL3 under basal conditions but is displaced by GBPL3 LLPS when it enters the nucleus following immune cues to drive the formation of unique membraneless organelles termed GBPL defence-activated condensates (GDACs) that we visualized by in situ cryo-electron tomography. Within these mesoscale GDAC structures, native GBPL3 directly bound defence-gene promoters and recruited specific transcriptional coactivators of the Mediator complex and RNA polymerase II machinery to massively reprogram host gene expression for disease resistance. Together, our study identifies a GBPL circuit that reinforces the biological importance of phase-separated condensates, in this case, as indispensable players in plant defence.

Published

2021

27. Structure of the human Mediator-RNA polymerase II pre-initiation complex.

Author

Rengachari S, Schilbach S, Aibara S, Dienemann C, and Cramer P

Subjects

Allosteric Regulation, Binding Sites, Catalytic Domain, Cyclin-Dependent Kinases chemistry, Cyclin-Dependent Kinases metabolism, DNA, Complementary genetics, Humans, Mediator Complex metabolism, Models, Molecular, Phosphorylation, Protein Binding, RNA Polymerase II metabolism, Transcription Factor TFIIB chemistry, Transcription Factor TFIIB metabolism, Transcription Factors, TFII chemistry, Transcription Factors, TFII metabolism, Transcription Initiation, Genetic, Cyclin-Dependent Kinase-Activating Kinase, Cryoelectron Microscopy, Mediator Complex chemistry, Mediator Complex ultrastructure, RNA Polymerase II chemistry, RNA Polymerase II ultrastructure

Abstract

Mediator is a conserved coactivator complex that enables the regulated initiation of transcription at eukaryotic genes 1-3 . Mediator is recruited by transcriptional activators and binds the pre-initiation complex (PIC) to stimulate the phosphorylation of RNA polymerase II (Pol II) and promoter escape 1-6 . Here we prepare a recombinant version of human Mediator, reconstitute a 50-subunit Mediator-PIC complex and determine the structure of the complex by cryo-electron microscopy. The head module of Mediator contacts the stalk of Pol II and the general transcription factors TFIIB and TFIIE, resembling the Mediator-PIC interactions observed in the corresponding complex in yeast 7-9 . The metazoan subunits MED27-MED30 associate with exposed regions in MED14 and MED17 to form the proximal part of the Mediator tail module that binds activators. Mediator positions the flexibly linked cyclin-dependent kinase (CDK)-activating kinase of the general transcription factor TFIIH near the linker to the C-terminal repeat domain of Pol II. The Mediator shoulder domain holds the CDK-activating kinase subunit CDK7, whereas the hook domain contacts a CDK7 element that flanks the kinase active site. The shoulder and hook domains reside in the Mediator head and middle modules, respectively, which can move relative to each other and may induce an active conformation of the CDK7 kinase to allosterically stimulate phosphorylation of the C-terminal domain.

Published

2021

28. Novel role of CAP1 in regulation RNA polymerase II-mediated transcription elongation depends on its actin-depolymerization activity in nucleoplasm.

Author

Zhang Q, Tang Q, Liu W, Hu C, Liu X, Liu Y, Zhou M, Lai W, Sheng F, Yang H, Huang J, and Li G

Subjects

Animals, Cell Cycle Proteins genetics, Cell Line, Tumor, Cell Movement, Cell Proliferation, Cyclin-Dependent Kinase 9 genetics, Cytoskeletal Proteins genetics, Heterografts, Humans, Lung Neoplasms genetics, Lung Neoplasms pathology, Male, Mice, Mice, Nude, Phosphorylation, Polymerization, RNA Polymerase II genetics, Survival Rate, Actins metabolism, Cell Cycle Proteins metabolism, Cyclin-Dependent Kinase 9 metabolism, Cytoskeletal Proteins metabolism, Lung Neoplasms metabolism, RNA Polymerase II metabolism

Abstract

Lung cancer is one of the most intractable diseases with high incidence and mortality worldwide. Adenylate cyclase-associated protein 1 (CAP1), a well-known actin depolymerization factor, is recently reported to be an oncogene accelerating cancer cell proliferation. However, the physiological significance of CAP1 in lung cancer is incompletely understood and the novel functions of CAP1 in transcriptional regulation remain unknown. Here we found that CAP1 was highly expressed in lung cancer tissues and cells, which was also negatively associated with prognosis in lung cancer patients. Moreover, CAP1 promoted A549 cells proliferation by promoting protein synthesis to accelerate cell cycle progression. Mechanistically, we revealed that CAP1 facilitated cyclin-dependent kinase 9 (CDK9)-mediated RNA polymerases (Pol) II-Ser2 phosphorylation and subsequent transcription elongation, and CAP1 performed its function in this progress depending on its actin-depolymerization activity in nucleoplasm. Furthermore, our in vivo findings confirmed that CAP1-promoted A549 xenograft tumor growth was associated with CDK9-mediated Pol II-Ser2 phosphorylation. Our study elucidates a novel role of CAP1 in modulating transcription by promoting polymerase II phosphorylation and suggests that CAP1 is a newly identified biomarker for lung cancer treatment and prognosis prediction.

Published

2021

29. A high-resolution protein architecture of the budding yeast genome.

Author

Rossi MJ, Kuntala PK, Lai WKM, Yamada N, Badjatia N, Mittal C, Kuzu G, Bocklund K, Farrell NP, Blanda TR, Mairose JD, Basting AV, Mistretta KS, Rocco DJ, Perkinson ES, Kellogg GD, Mahony S, and Pugh BF

Subjects

Coenzymes metabolism, Multiprotein Complexes metabolism, Promoter Regions, Genetic, RNA Polymerase I metabolism, RNA Polymerase II metabolism, RNA Polymerase III metabolism, TATA-Box Binding Protein genetics, TATA-Box Binding Protein metabolism, Transcription Factor TFIIB genetics, Transcription Factor TFIIB metabolism, Transcription Factor TFIID, Transcription Factors metabolism, Fungal Proteins genetics, Fungal Proteins metabolism, Genome, Fungal genetics, Multiprotein Complexes genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Transcription Factors genetics

Abstract

The genome-wide architecture of chromatin-associated proteins that maintains chromosome integrity and gene regulation is not well defined. Here we use chromatin immunoprecipitation, exonuclease digestion and DNA sequencing (ChIP-exo/seq) 1,2 to define this architecture in Saccharomyces cerevisiae. We identify 21 meta-assemblages consisting of roughly 400 different proteins that are related to DNA replication, centromeres, subtelomeres, transposons and transcription by RNA polymerase (Pol) I, II and III. Replication proteins engulf a nucleosome, centromeres lack a nucleosome, and repressive proteins encompass three nucleosomes at subtelomeric X-elements. We find that most promoters associated with Pol II evolved to lack a regulatory region, having only a core promoter. These constitutive promoters comprise a short nucleosome-free region (NFR) adjacent to a +1 nucleosome, which together bind the transcription-initiation factor TFIID to form a preinitiation complex. Positioned insulators protect core promoters from upstream events. A small fraction of promoters evolved an architecture for inducibility, whereby sequence-specific transcription factors (ssTFs) create a nucleosome-depleted region (NDR) that is distinct from an NFR. We describe structural interactions among ssTFs, their cognate cofactors and the genome. These interactions include the nucleosomal and transcriptional regulators RPD3-L, SAGA, NuA4, Tup1, Mediator and SWI-SNF. Surprisingly, we do not detect interactions between ssTFs and TFIID, suggesting that such interactions do not stably occur. Our model for gene induction involves ssTFs, cofactors and general factors such as TBP and TFIIB, but not TFIID. By contrast, constitutive transcription involves TFIID but not ssTFs engaged with their cofactors. From this, we define a highly integrated network of gene regulation by ssTFs.

Published

2021

30. Comparative proteomics identifies Schlafen 5 (SLFN5) as a herpes simplex virus restriction factor that suppresses viral transcription.

Author

Kim ET, Dybas JM, Kulej K, Reyes ED, Price AM, Akhtar LN, Orr A, Garcia BA, Boutell C, and Weitzman MD

Subjects

Animals, Cell Cycle Proteins genetics, Chlorocebus aethiops, DNA, Viral metabolism, HEK293 Cells, HeLa Cells, Herpes Simplex metabolism, Humans, Immediate-Early Proteins genetics, Immediate-Early Proteins metabolism, Promoter Regions, Genetic, Proteomics, RNA Polymerase II metabolism, Ubiquitin-Protein Ligases genetics, Ubiquitin-Protein Ligases metabolism, Ubiquitination, Vero Cells, Cell Cycle Proteins metabolism, Gene Expression Regulation, Viral, Herpes Simplex virology, Host-Pathogen Interactions, Simplexvirus genetics, Transcription, Genetic

Abstract

Intrinsic antiviral host factors confer cellular defence by limiting virus replication and are often counteracted by viral countermeasures. We reasoned that host factors that inhibit viral gene expression could be identified by determining proteins bound to viral DNA (vDNA) in the absence of key viral antagonists. Herpes simplex virus 1 (HSV-1) expresses E3 ubiquitin-protein ligase ICP0 (ICP0), which functions as an E3 ubiquitin ligase required to promote infection. Cellular substrates of ICP0 have been discovered as host barriers to infection but the mechanisms for inhibition of viral gene expression are not fully understood. To identify restriction factors antagonized by ICP0, we compared proteomes associated with vDNA during HSV-1 infection with wild-type virus and a mutant lacking functional ICP0 (ΔICP0). We identified the cellular protein Schlafen family member 5 (SLFN5) as an ICP0 target that binds vDNA during HSV-1 ΔICP0 infection. We demonstrated that ICP0 mediates ubiquitination of SLFN5, which leads to its proteasomal degradation. In the absence of ICP0, SLFN5 binds vDNA to repress HSV-1 transcription by limiting accessibility of RNA polymerase II to viral promoters. These results highlight how comparative proteomics of proteins associated with viral genomes can identify host restriction factors and reveal that viral countermeasures can overcome SLFN antiviral activity.

Published

2021

31. Current understanding of CREPT and p15RS, carboxy-terminal domain (CTD)-interacting proteins, in human cancers.

Author

Li M, Ma D, and Chang Z

Subjects

Cell Cycle, DNA Repair, Gene Expression Regulation, Neoplastic, Humans, Neoplasms genetics, RNA Polymerase II metabolism, Transcription, Genetic, Cell Cycle Proteins physiology, Neoplasm Proteins physiology, Neoplasms etiology, Repressor Proteins physiology

Abstract

CREPT and p15RS, also named RPRD1B and RPRD1A, are RPRD (regulation of nuclear pre-mRNA-domain-containing) proteins containing C-terminal domain (CTD)-interacting domain (CID), which mediates the binding to the CTD of Rpb1, the largest subunit of RNA polymerase II (RNAPII). CREPT and p15RS are highly conserved, with a common yeast orthologue Rtt103. Intriguingly, human CREPT and p15RS possess opposite functions in the regulation of cell proliferation and tumorigenesis. While p15RS inhibits cell proliferation, CREPT promotes cell cycle and tumor growth. Aberrant expression of both CREPT and p15RS was found in numerous types of cancers. At the molecular level, both CREPT and p15RS were reported to regulate gene transcription by interacting with RNAPII. However, CREPT also exerts a key function in the processes linked to DNA damage repairs. In this review, we summarized the recent studies regarding the biological roles of CREPT and p15RS, as well as the molecular mechanisms underlying their activities. Fully revealing the mechanisms of CREPT and p15RS functions will not only provide new insights into understanding gene transcription and maintenance of DNA stability in tumors, but also promote new approach development for tumor diagnosis and therapy.

Published

2021

32. The landscape of RNA Pol II binding reveals a stepwise transition during ZGA.

Author

Liu B, Xu Q, Wang Q, Feng S, Lai F, Wang P, Zheng F, Xiang Y, Wu J, Nie J, Qiu C, Xia W, Li L, Yu G, Lin Z, Xu K, Xiong Z, Kong F, Liu L, Huang C, Yu Y, Na J, and Xie W

Subjects

Alleles, Animals, Chromatin genetics, Chromatin metabolism, Embryo, Mammalian cytology, Embryo, Mammalian enzymology, Embryo, Mammalian metabolism, Epigenome genetics, Female, Male, Maternal Inheritance genetics, Mice, Mice, Inbred C57BL, Oocytes enzymology, Oocytes metabolism, Promoter Regions, Genetic genetics, RNA Polymerase II genetics, Zygote cytology, Zygote enzymology, Gene Expression Regulation, Developmental genetics, Genome genetics, RNA Polymerase II metabolism, Zygote metabolism

Abstract

Zygotic genome activation (ZGA) is the first transcription event in life 1 . However, it is unclear how RNA polymerase is engaged in initiating ZGA in mammals. Here, by developing small-scale Tn5-assisted chromatin cleavage with sequencing (Stacc-seq), we investigated the landscapes of RNA polymerase II (Pol II) binding in mouse embryos. We found that Pol II undergoes 'loading', 'pre-configuration', and 'production' during the transition from minor ZGA to major ZGA. After fertilization, Pol II is preferentially loaded to CG-rich promoters and accessible distal regions in one-cell embryos (loading), in part shaped by the inherited parental epigenome. Pol II then initiates relocation to future gene targets before genome activation (pre-configuration), where it later engages in full transcription elongation upon major ZGA (production). Pol II also maintains low poising at inactive promoters after major ZGA until the blastocyst stage, coinciding with the loss of promoter epigenetic silencing factors. Notably, inhibition of minor ZGA impairs the Pol II pre-configuration and embryonic development, accompanied by aberrant retention of Pol II and ectopic expression of one-cell targets upon major ZGA. Hence, stepwise transition of Pol II occurs when mammalian life begins, and minor ZGA has a key role in the pre-configuration of transcription machinery and chromatin for genome activation.

Published

2020

33. Identification of the human DPR core promoter element using machine learning.

Author

Vo Ngoc L, Huang CY, Cassidy CJ, Medrano C, and Kadonaga JT

Subjects

Base Sequence, Cells metabolism, Computer Simulation, Datasets as Topic, HeLa Cells, High-Throughput Nucleotide Sequencing, Humans, Models, Genetic, Mutagenesis, TATA Box genetics, Consensus Sequence genetics, Gene Expression Regulation genetics, Promoter Regions, Genetic genetics, RNA Polymerase II metabolism, Support Vector Machine, Transcription, Genetic

Abstract

The RNA polymerase II (Pol II) core promoter is the strategic site of convergence of the signals that lead to the initiation of DNA transcription 1-5 , but the downstream core promoter in humans has been difficult to understand 1-3 . Here we analyse the human Pol II core promoter and use machine learning to generate predictive models for the downstream core promoter region (DPR) and the TATA box. We developed a method termed HARPE (high-throughput analysis of randomized promoter elements) to create hundreds of thousands of DPR (or TATA box) variants, each with known transcriptional strength. We then analysed the HARPE data by support vector regression (SVR) to provide comprehensive models for the sequence motifs, and found that the SVR-based approach is more effective than a consensus-based method for predicting transcriptional activity. These results show that the DPR is a functionally important core promoter element that is widely used in human promoters. Notably, there appears to be a duality between the DPR and the TATA box, as many promoters contain one or the other element. More broadly, these findings show that functional DNA motifs can be identified by machine learning analysis of a comprehensive set of sequence variants.

Published

2020

34. Nucleolar RNA polymerase II drives ribosome biogenesis.

Author

Abraham KJ, Khosraviani N, Chan JNY, Gorthi A, Samman A, Zhao DY, Wang M, Bokros M, Vidya E, Ostrowski LA, Oshidari R, Pietrobon V, Patel PS, Algouneh A, Singhania R, Liu Y, Yerlici VT, De Carvalho DD, Ohh M, Dickson BC, Hakem R, Greenblatt JF, Lee S, Bishop AJR, and Mekhail K

Subjects

CRISPR-Associated Protein 9 genetics, CRISPR-Associated Protein 9 metabolism, Cell Line, Tumor, Cell Nucleolus physiology, DNA Helicases metabolism, DNA, Intergenic genetics, Humans, Multifunctional Enzymes metabolism, Protein Biosynthesis, R-Loop Structures, RNA Helicases metabolism, RNA Polymerase I antagonists & inhibitors, RNA Polymerase I metabolism, Ribonuclease H metabolism, Ribosomes chemistry, Ribosomes genetics, Sarcoma, Ewing genetics, Sarcoma, Ewing pathology, Cell Nucleolus enzymology, Cell Nucleolus genetics, DNA, Ribosomal genetics, RNA Polymerase II metabolism, RNA, Untranslated biosynthesis, RNA, Untranslated genetics, Ribosomes metabolism

Abstract

Proteins are manufactured by ribosomes-macromolecular complexes of protein and RNA molecules that are assembled within major nuclear compartments called nucleoli 1,2 . Existing models suggest that RNA polymerases I and III (Pol I and Pol III) are the only enzymes that directly mediate the expression of the ribosomal RNA (rRNA) components of ribosomes. Here we show, however, that RNA polymerase II (Pol II) inside human nucleoli operates near genes encoding rRNAs to drive their expression. Pol II, assisted by the neurodegeneration-associated enzyme senataxin, generates a shield comprising triplex nucleic acid structures known as R-loops at intergenic spacers flanking nucleolar rRNA genes. The shield prevents Pol I from producing sense intergenic noncoding RNAs (sincRNAs) that can disrupt nucleolar organization and rRNA expression. These disruptive sincRNAs can be unleashed by Pol II inhibition, senataxin loss, Ewing sarcoma or locus-associated R-loop repression through an experimental system involving the proteins RNaseH1, eGFP and dCas9 (which we refer to as 'red laser'). We reveal a nucleolar Pol-II-dependent mechanism that drives ribosome biogenesis, identify disease-associated disruption of nucleoli by noncoding RNAs, and establish locus-targeted R-loop modulation. Our findings revise theories of labour division between the major RNA polymerases, and identify nucleolar Pol II as a major factor in protein synthesis and nuclear organization, with potential implications for health and disease.

Published

2020

35. Ex vivo rescue of recombinant very virulent IBDV using a RNA polymerase II driven system and primary chicken bursal cells.

Author

Cubas-Gaona LL, Trombetta R, Courtillon C, Li K, Qi X, Wang X, Lotmani S, Keita A, Amelot M, Eterradossi N, and Soubies SM

Subjects

Animals, B-Lymphocytes virology, Capsid Proteins genetics, Cell Line, Chickens, Virulence, DNA, Recombinant genetics, Infectious bursal disease virus genetics, Infectious bursal disease virus pathogenicity, RNA Polymerase II metabolism

Abstract

Infectious Bursal Disease Virus (IBDV), a member of the Birnaviridae family, causes an immunosuppressive disease in young chickens. Although several reverse genetics systems are available for IBDV, the isolation of most field-derived strains, such as very virulent IBDV (vvIBDV) and their subsequent rescue, has remained challenging due to the lack of replication of those viruses in vitro. Such rescue required either the inoculation of animals, embryonated eggs, or the introduction of mutations in the capsid protein (VP2) hypervariable region (HVR) to adapt the virus to cell culture, the latter option concomitantly altering its virulence in vivo. We describe an improved ex vivo IBDV rescue system based on the transfection of an avian cell line with RNA polymerase II-based expression vectors, combined with replication on primary chicken bursal cells, the main cell type targeted in vivo of IBDV. We validated this system by rescuing to high titers two recombinant IBDV strains: a cell-culture adapted attenuated strain and a vvIBDV. Sequencing of VP2 HVR confirmed the absence of unwanted mutations that may alter the biological properties of the recombinant viruses. Therefore, this approach is efficient, economical, time-saving, reduces animal suffering and can be used to rescue other non-cell culture adapted IBDV strains.

Published

2020

36. Stress proteins: the biological functions in virus infection, present and challenges for target-based antiviral drug development.

Author

Wan Q, Song D, Li H, and He ML

Subjects

Antiviral Agents chemical synthesis, Betacoronavirus genetics, Betacoronavirus pathogenicity, COVID-19, Chromatin Assembly and Disassembly drug effects, Coronavirus Infections genetics, Coronavirus Infections pathology, Coronavirus Infections virology, Gene Expression Regulation, Heat-Shock Proteins agonists, Heat-Shock Proteins antagonists & inhibitors, Heat-Shock Proteins metabolism, Heterogeneous-Nuclear Ribonucleoproteins agonists, Heterogeneous-Nuclear Ribonucleoproteins antagonists & inhibitors, Heterogeneous-Nuclear Ribonucleoproteins metabolism, Host-Pathogen Interactions genetics, Humans, Molecular Targeted Therapy methods, Pandemics, Pneumonia, Viral genetics, Pneumonia, Viral pathology, Pneumonia, Viral virology, RNA Polymerase II genetics, RNA Polymerase II metabolism, RNA Precursors genetics, RNA Precursors metabolism, SARS-CoV-2, Severity of Illness Index, Signal Transduction, Transcription, Genetic drug effects, Virus Replication drug effects, Antiviral Agents pharmacology, Betacoronavirus drug effects, Coronavirus Infections drug therapy, Heat-Shock Proteins genetics, Heterogeneous-Nuclear Ribonucleoproteins genetics, Host-Pathogen Interactions drug effects, Pneumonia, Viral drug therapy

Abstract

Stress proteins (SPs) including heat-shock proteins (HSPs), RNA chaperones, and ER associated stress proteins are molecular chaperones essential for cellular homeostasis. The major functions of HSPs include chaperoning misfolded or unfolded polypeptides, protecting cells from toxic stress, and presenting immune and inflammatory cytokines. Regarded as a double-edged sword, HSPs also cooperate with numerous viruses and cancer cells to promote their survival. RNA chaperones are a group of heterogeneous nuclear ribonucleoproteins (hnRNPs), which are essential factors for manipulating both the functions and metabolisms of pre-mRNAs/hnRNAs transcribed by RNA polymerase II. hnRNPs involve in a large number of cellular processes, including chromatin remodelling, transcription regulation, RNP assembly and stabilization, RNA export, virus replication, histone-like nucleoid structuring, and even intracellular immunity. Dysregulation of stress proteins is associated with many human diseases including human cancer, cardiovascular diseases, neurodegenerative diseases (e.g., Parkinson's diseases, Alzheimer disease), stroke and infectious diseases. In this review, we summarized the biologic function of stress proteins, and current progress on their mechanisms related to virus reproduction and diseases caused by virus infections. As SPs also attract a great interest as potential antiviral targets (e.g., COVID-19), we also discuss the present progress and challenges in this area of HSP-based drug development, as well as with compounds already under clinical evaluation.

Published

2020

37. Gene expression regulation by CDK12: a versatile kinase in cancer with functions beyond CTD phosphorylation.

Author

Choi SH, Kim S, and Jones KA

Subjects

Animals, Biological Evolution, Cyclin-Dependent Kinases chemistry, Cyclin-Dependent Kinases genetics, Humans, Neoplasms etiology, Neoplasms metabolism, Neoplasms pathology, Phosphorylation, Protein Biosynthesis, RNA Polymerase II metabolism, Structure-Activity Relationship, Transcription Factors metabolism, Cyclin-Dependent Kinases metabolism, Gene Expression Regulation

Abstract

Cyclin-dependent kinases (CDKs) play critical roles in cell cycle progression and gene expression regulation. In human cancer, transcription-associated CDKs can activate oncogenic gene expression programs, whereas cell cycle-regulatory CDKs mainly induce uncontrolled proliferation. Cyclin-dependent kinase 12 (CDK12) belongs to the CDK family of serine/threonine kinases and has been recently found to have multiple roles in gene expression regulation and tumorigenesis. Originally, CDK12 was thought to be one of the transcription-associated CDKs, acting with its cyclin partner Cyclin K to promote the phosphorylation of the C-terminal domain (CTD) of RNA polymerase II and induce transcription elongation. However, recent studies have demonstrated that CDK12 also controls multiple gene expression processes, including transcription termination, mRNA splicing, and translation. Most importantly, CDK12 mutations are frequently found in human tumors. Loss of CDK12 function causes defective expression of DNA damage response (DDR) genes, which eventually results in genome instability, a hallmark of human cancer. Here, we discuss the diverse roles of CDK12 in gene expression regulation and human cancer, focusing on newly identified CDK12 kinase functions in cellular processes and highlighting CDK12 as a promising therapeutic target for human cancer treatment.

Published

2020

38. U1 snRNP regulates chromatin retention of noncoding RNAs.

Author

Yin Y, Lu JY, Zhang X, Shao W, Xu Y, Li P, Hong Y, Cui L, Shan G, Tian B, Zhang QC, and Shen X

Subjects

Animals, Cell Line, High-Throughput Nucleotide Sequencing, Humans, Mice, Mouse Embryonic Stem Cells metabolism, Mutagenesis, Nucleotide Motifs, RNA Polymerase II metabolism, RNA Precursors genetics, RNA Precursors metabolism, RNA Splice Sites, RNA, Long Noncoding genetics, RNA, Small Nuclear genetics, RNA, Small Nuclear metabolism, Chromatin genetics, Chromatin metabolism, RNA, Long Noncoding metabolism, Ribonucleoprotein, U1 Small Nuclear metabolism, Transcription, Genetic

Abstract

Long noncoding RNAs (lncRNAs) and promoter- or enhancer-associated unstable transcripts locate preferentially to chromatin, where some regulate chromatin structure, transcription and RNA processing 1-13 . Although several RNA sequences responsible for nuclear localization have been identified-such as repeats in the lncRNA Xist and Alu-like elements in long RNAs 14-16 -how lncRNAs as a class are enriched at chromatin remains unknown. Here we describe a random, mutagenesis-coupled, high-throughput method that we name 'RNA elements for subcellular localization by sequencing' (mutREL-seq). Using this method, we discovered an RNA motif that recognizes the U1 small nuclear ribonucleoprotein (snRNP) and is essential for the localization of reporter RNAs to chromatin. Across the genome, chromatin-bound lncRNAs are enriched with 5' splice sites and depleted of 3' splice sites, and exhibit high levels of U1 snRNA binding compared with cytoplasm-localized messenger RNAs. Acute depletion of U1 snRNA or of the U1 snRNP protein component SNRNP70 markedly reduces the chromatin association of hundreds of lncRNAs and unstable transcripts, without altering the overall transcription rate in cells. In addition, rapid degradation of SNRNP70 reduces the localization of both nascent and polyadenylated lncRNA transcripts to chromatin, and disrupts the nuclear and genome-wide localization of the lncRNA Malat1. Moreover, U1 snRNP interacts with transcriptionally engaged RNA polymerase II. These results show that U1 snRNP acts widely to tether and mobilize lncRNAs to chromatin in a transcription-dependent manner. Our findings have uncovered a previously unknown role of U1 snRNP beyond the processing of precursor mRNA, and provide molecular insight into how lncRNAs are recruited to regulatory sites to carry out chromatin-associated functions.

Published

2020

39. Defective transcription of ATF3 responsive genes, a marker for Cockayne Syndrome.

Author

Epanchintsev A, Rauschendorf MA, Costanzo F, Calmels N, Obringer C, Sarasin A, Coin F, Laugel V, and Egly JM

Subjects

Activating Transcription Factor 3 metabolism, Cell Cycle Proteins, Cell Line, DNA Damage, DNA Helicases genetics, DNA Repair Enzymes genetics, Gene Expression Profiling, Humans, Mutation, Nerve Tissue Proteins, Neuregulin-1, Poly-ADP-Ribose Binding Proteins genetics, RNA Polymerase II metabolism, Transcription Factors genetics, Ultraviolet Rays, Activating Transcription Factor 3 genetics, Cockayne Syndrome diagnosis, Cockayne Syndrome genetics, Genes, Immediate-Early genetics, Genetic Markers, Transcription, Genetic genetics

Abstract

Cockayne syndrome (CS) is a rare genetic disorder caused by mutations (dysfunction) in CSA and CSB. CS patients exhibit mild photosensitivity and severe neurological problems. Currently, CS diagnosis is based on the inefficiency of CS cells to recover RNA synthesis upon genotoxic (UV) stress. Indeed, upon genotoxic stress, ATF3, an immediate early gene is activated to repress up to 5000 genes encompassing its responsive element for a short period of time. On the contrary in CS cells, CSA and CSB dysfunction impairs the degradation of the chromatin-bound ATF3, leading to a permanent transcriptional arrest as observed by immunofluorescence and ChIP followed by RT-PCR. We analysed ChIP-seq of Pol II and ATF3 promoter occupation analysis and RNA sequencing-based gene expression profiling in CS cells, as well as performed immunofluorescence study of ATF3 protein stability and quantitative RT-PCR screening in 64 patient cell lines. We show that the analysis of few amount (as for example CDK5RAP2, NIPBL and NRG1) of ATF3 dependent genes, could serve as prominent molecular markers to discriminate between CS and non-CS patient's cells. Such assay can significantly simplify the timing and the complexity of the CS diagnostic procedure in comparison to the currently available methods.

Published

2020

40. Negative supercoil at gene boundaries modulates gene topology.

Author

Achar YJ, Adhil M, Choudhary R, Gilbert N, and Foiani M

Subjects

Chromatin Assembly and Disassembly, DNA Replication, DNA Topoisomerases, Type I metabolism, DNA Topoisomerases, Type II genetics, DNA Topoisomerases, Type II metabolism, DNA, Cruciform chemistry, DNA, Cruciform genetics, DNA, Cruciform metabolism, DNA, Fungal genetics, DNA, Fungal metabolism, DNA, Superhelical genetics, DNA, Superhelical metabolism, G1 Phase, Gene Expression Regulation, Fungal, High Mobility Group Proteins metabolism, Mutation, Nucleic Acid Hybridization, Nucleosomes chemistry, Nucleosomes genetics, Nucleosomes metabolism, Open Reading Frames genetics, RNA Polymerase II genetics, RNA Polymerase II metabolism, RNA, Fungal chemistry, RNA, Fungal genetics, RNA, Fungal metabolism, S Phase, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae Proteins metabolism, Transcription, Genetic, DNA, Fungal chemistry, DNA, Superhelical chemistry, Genes, Fungal, Saccharomyces cerevisiae cytology, Saccharomyces cerevisiae genetics

Abstract

Transcription challenges the integrity of replicating chromosomes by generating topological stress and conflicts with forks 1,2 . The DNA topoisomerases Top1 and Top2 and the HMGB family protein Hmo1 assist DNA replication and transcription 3-6 . Here we describe the topological architecture of genes in Saccharomyces cerevisiae during the G1 and S phases of the cell cycle. We found under-wound DNA at gene boundaries and over-wound DNA within coding regions. This arrangement does not depend on Pol II or S phase. Top2 and Hmo1 preserve negative supercoil at gene boundaries, while Top1 acts at coding regions. Transcription generates RNA-DNA hybrids within coding regions, independently of fork orientation. During S phase, Hmo1 protects under-wound DNA from Top2, while Top2 confines Pol II and Top1 at coding units, counteracting transcription leakage and aberrant hybrids at gene boundaries. Negative supercoil at gene boundaries prevents supercoil diffusion and nucleosome repositioning at coding regions. DNA looping occurs at Top2 clusters. We propose that Hmo1 locks gene boundaries in a cruciform conformation and, with Top2, modulates the architecture of genes that retain the memory of the topological arrangements even when transcription is repressed.

Published

2020

41. A SUMO-dependent pathway controls elongating RNA Polymerase II upon UV-induced damage.

Author

Heckmann I, Kern MJ, Pfander B, and Jentsch S

Subjects

Proteasome Endopeptidase Complex metabolism, RNA Polymerase II genetics, Saccharomyces cerevisiae, Saccharomyces cerevisiae Proteins genetics, Ubiquitin-Protein Ligases genetics, Ubiquitin-Protein Ligases metabolism, Ultraviolet Rays, Valosin Containing Protein genetics, Valosin Containing Protein metabolism, DNA Damage, RNA Polymerase II metabolism, Saccharomyces cerevisiae Proteins metabolism, Sumoylation

Abstract

RNA polymerase II (RNAPII) is the workhorse of eukaryotic transcription and produces messenger RNAs and small nuclear RNAs. Stalling of RNAPII caused by transcription obstacles such as DNA damage threatens functional gene expression and is linked to transcription-coupled DNA repair. To restore transcription, persistently stalled RNAPII can be disassembled and removed from chromatin. This process involves several ubiquitin ligases that have been implicated in RNAPII ubiquitylation and proteasomal degradation. Transcription by RNAPII is heavily controlled by phosphorylation of the C-terminal domain of its largest subunit Rpb1. Here, we show that the elongating form of Rpb1, marked by S2 phosphorylation, is specifically controlled upon UV-induced DNA damage. Regulation of S2-phosphorylated Rpb1 is mediated by SUMOylation, the SUMO-targeted ubiquitin ligase Slx5-Slx8, the Cdc48 segregase as well as the proteasome. Our data suggest an RNAPII control pathway with striking parallels to known disassembly mechanisms acting on defective RNA polymerase III.

Published

2019

42. Coordinated alterations in RNA splicing and epigenetic regulation drive leukaemogenesis.

Author

Yoshimi A, Lin KT, Wiseman DH, Rahman MA, Pastore A, Wang B, Lee SC, Micol JB, Zhang XJ, de Botton S, Penard-Lacronique V, Stein EM, Cho H, Miles RE, Inoue D, Albrecht TR, Somervaille TCP, Batta K, Amaral F, Simeoni F, Wilks DP, Cargo C, Intlekofer AM, Levine RL, Dvinge H, Bradley RK, Wagner EJ, Krainer AR, and Abdel-Wahab O

Subjects

Animals, Cell Line, Tumor, Cell Proliferation, DNA Methylation, DNA-Binding Proteins genetics, Female, Gene Expression Regulation, Neoplastic, Humans, Isocitrate Dehydrogenase genetics, Male, Mutation genetics, RNA Polymerase II metabolism, Serine-Arginine Splicing Factors genetics, Transcriptome, Alternative Splicing genetics, Carcinogenesis genetics, Epigenesis, Genetic, Leukemia, Myeloid, Acute genetics

Abstract

Transcription and pre-mRNA splicing are key steps in the control of gene expression and mutations in genes regulating each of these processes are common in leukaemia 1,2 . Despite the frequent overlap of mutations affecting epigenetic regulation and splicing in leukaemia, how these processes influence one another to promote leukaemogenesis is not understood and, to our knowledge, there is no functional evidence that mutations in RNA splicing factors initiate leukaemia. Here, through analyses of transcriptomes from 982 patients with acute myeloid leukaemia, we identified frequent overlap of mutations in IDH2 and SRSF2 that together promote leukaemogenesis through coordinated effects on the epigenome and RNA splicing. Whereas mutations in either IDH2 or SRSF2 imparted distinct splicing changes, co-expression of mutant IDH2 altered the splicing effects of mutant SRSF2 and resulted in more profound splicing changes than either mutation alone. Consistent with this, co-expression of mutant IDH2 and SRSF2 resulted in lethal myelodysplasia with proliferative features in vivo and enhanced self-renewal in a manner not observed with either mutation alone. IDH2 and SRSF2 double-mutant cells exhibited aberrant splicing and reduced expression of INTS3, a member of the integrator complex 3 , concordant with increased stalling of RNA polymerase II (RNAPII). Aberrant INTS3 splicing contributed to leukaemogenesis in concert with mutant IDH2 and was dependent on mutant SRSF2 binding to cis elements in INTS3 mRNA and increased DNA methylation of INTS3. These data identify a pathogenic crosstalk between altered epigenetic state and splicing in a subset of leukaemias, provide functional evidence that mutations in splicing factors drive myeloid malignancy development, and identify spliceosomal changes as a mediator of IDH2-mutant leukaemogenesis.

Published

2019

43. de novo MEPCE nonsense variant associated with a neurodevelopmental disorder causes disintegration of 7SK snRNP and enhanced RNA polymerase II activation.

Author

Schneeberger PE, Bierhals T, Neu A, Hempel M, and Kutsche K

Subjects

Child, Child, Preschool, Codon, Nonsense, Humans, Male, Methyltransferases metabolism, Neurodevelopmental Disorders metabolism, Positive Transcriptional Elongation Factor B genetics, Positive Transcriptional Elongation Factor B metabolism, RNA Polymerase II genetics, RNA, Small Nuclear genetics, RNA-Binding Proteins genetics, RNA-Binding Proteins metabolism, Ribonucleoproteins genetics, Ribonucleoproteins metabolism, Transcription Factors genetics, Transcription Factors metabolism, Transcription, Genetic, Methyltransferases genetics, Neurodevelopmental Disorders genetics, RNA Polymerase II metabolism, RNA, Small Nuclear metabolism

Abstract

In eukaryotes, the elongation phase of transcription by RNA polymerase II (RNAP II) is regulated by the transcription elongation factor b (P-TEFb), composed of Cyclin-T1 and cyclin-dependent kinase 9. The release of RNAP II is mediated by phosphorylation through P-TEFb that in turn is under control by the inhibitory 7SK small nuclear ribonucleoprotein (snRNP) complex. The 7SK snRNP consists of the 7SK non-coding RNA and the proteins MEPCE, LARP7, and HEXIM1/2. Biallelic LARP7 loss-of-function variants underlie Alazami syndrome characterized by growth retardation and intellectual disability. We report a boy with global developmental delay and seizures carrying the de novo MEPCE nonsense variant c.1552 C > T/p.(Arg518*). mRNA and protein analyses identified nonsense-mediated mRNA decay to underlie the decreased amount of MEPCE in patient fibroblasts followed by LARP7 and 7SK snRNA downregulation and HEXIM1 upregulation. Reduced binding of HEXIM1 to Cyclin-T1, hyperphosphorylation of the RNAP II C-terminal domain, and upregulated expression of ID2, ID3, MRPL11 and snRNAs U1, U2 and U4 in patient cells are suggestive of enhanced activation of P-TEFb. Flavopiridol treatment and ectopic MEPCE protein expression in patient fibroblasts rescued increased expression of six RNAP II-sensitive genes and suggested a possible repressive effect of MEPCE on P-TEFb-dependent transcription of specific genes.

Published

2019

44. Pol II phosphorylation regulates a switch between transcriptional and splicing condensates.

Author

Guo YE, Manteiga JC, Henninger JE, Sabari BR, Dall'Agnese A, Hannett NM, Spille JH, Afeyan LK, Zamudio AV, Shrinivas K, Abraham BJ, Boija A, Decker TM, Rimel JK, Fant CB, Lee TI, Cisse II, Sharp PA, Taatjes DJ, and Young RA

Subjects

Animals, Cell Line, Enhancer Elements, Genetic genetics, Gene Expression Regulation genetics, Humans, Mediator Complex genetics, Mice, Phosphorylation, Protein Domains, RNA Polymerase II genetics, RNA Splicing Factors chemistry, RNA Splicing Factors genetics, RNA Splicing Factors metabolism, Mediator Complex chemistry, Mediator Complex metabolism, RNA Polymerase II chemistry, RNA Polymerase II metabolism, RNA Splicing, Transcription, Genetic

Abstract

The synthesis of pre-mRNA by RNA polymerase II (Pol II) involves the formation of a transcription initiation complex, and a transition to an elongation complex 1-4 . The large subunit of Pol II contains an intrinsically disordered C-terminal domain that is phosphorylated by cyclin-dependent kinases during the transition from initiation to elongation, thus influencing the interaction of the C-terminal domain with different components of the initiation or the RNA-splicing apparatus 5,6 . Recent observations suggest that this model provides only a partial picture of the effects of phosphorylation of the C-terminal domain 7-12 . Both the transcription-initiation machinery and the splicing machinery can form phase-separated condensates that contain large numbers of component molecules: hundreds of molecules of Pol II and mediator are concentrated in condensates at super-enhancers 7,8 , and large numbers of splicing factors are concentrated in nuclear speckles, some of which occur at highly active transcription sites 9-12 . Here we investigate whether the phosphorylation of the Pol II C-terminal domain regulates the incorporation of Pol II into phase-separated condensates that are associated with transcription initiation and splicing. We find that the hypophosphorylated C-terminal domain of Pol II is incorporated into mediator condensates and that phosphorylation by regulatory cyclin-dependent kinases reduces this incorporation. We also find that the hyperphosphorylated C-terminal domain is preferentially incorporated into condensates that are formed by splicing factors. These results suggest that phosphorylation of the Pol II C-terminal domain drives an exchange from condensates that are involved in transcription initiation to those that are involved in RNA processing, and implicates phosphorylation as a mechanism that regulates condensate preference.

Published

2019

45. SREBP1-dependent de novo fatty acid synthesis gene expression is elevated in malignant melanoma and represents a cellular survival trait.

Author

Wu S and Näär AM

Subjects

Cell Line, Tumor, Cell Survival, Extracellular Signal-Regulated MAP Kinases antagonists & inhibitors, Humans, Indazoles pharmacology, Kaplan-Meier Estimate, Melanoma genetics, Melanoma mortality, Neoplasm Proteins antagonists & inhibitors, Neoplasms genetics, Piperazines pharmacology, Prognosis, Proto-Oncogene Proteins B-raf antagonists & inhibitors, RNA Interference, RNA Polymerase II metabolism, RNA, Small Interfering genetics, Skin Neoplasms genetics, Skin Neoplasms mortality, Transcription, Genetic, Vemurafenib pharmacology, Fatty Acids biosynthesis, Gene Expression Regulation, Neoplastic drug effects, Melanoma metabolism, Neoplasm Proteins physiology, Skin Neoplasms metabolism, Sterol Regulatory Element Binding Protein 1 physiology

Abstract

de novo fatty acid biosynthesis (DNFA) is a hallmark adaptation of many cancers that supports survival, proliferation, and metastasis. Here we elucidate previously unexplored aspects of transcription regulation and clinical relevance of DNFA in cancers. We show that elevated expression of DNFA genes is characteristic of many tumor types and correlates with poor prognosis, especially in melanomas. Elevated DNFA gene expression depends on the SREBP1 transcription factor in multiple melanoma cell lines. SREBP1 predominantly binds to the transcription start sites of DNFA genes, regulating their expression by recruiting RNA polymerase II to promoters for productive transcription elongation. We find that SREBP1-regulated DNFA represents a survival trait in melanoma cells, regardless of proliferative state and oncogenic mutation status. Indeed, malignant melanoma cells exhibit elevated DNFA gene expression after the BRAF/MEK signaling pathway is blocked (e.g. by BRAF inhibitors), and DNFA expression remains higher in melanoma cells resistant to vemurafenib treatment than in untreated cells. Accordingly, DNFA pathway inhibition, whether by direct targeting of SREBP1 with antisense oligonucleotides, or through combinatorial effects of multiple DNFA enzyme inhibitors, exerts potent cytotoxic effects on both BRAFi-sensitive and -resistant melanoma cells. Altogether, these results implicate SREBP1 and DNFA enzymes as enticing therapeutic targets in melanomas.

Published

2019

46. Bromodomain inhibitor JQ1 reversibly blocks IFN-γ production.

Author

Gibbons HR, Mi DJ, Farley VM, Esmond T, Kaood MB, and Aune TM

Subjects

Adult, CD4-Positive T-Lymphocytes drug effects, CD4-Positive T-Lymphocytes immunology, Cells, Cultured, Down-Regulation, Humans, Killer Cells, Natural drug effects, Killer Cells, Natural immunology, Leukocytes, Mononuclear drug effects, Leukocytes, Mononuclear metabolism, RNA Polymerase II metabolism, Th1 Cells drug effects, Th1 Cells immunology, Azepines pharmacology, Interferon-gamma genetics, Leukocytes, Mononuclear cytology, Triazoles pharmacology

Abstract

As a class, 'BET' inhibitors disrupt binding of bromodomain and extra-terminal motif (BET) proteins, BRD2, BRD3, BRD4 and BRDT, to acetylated histones preventing recruitment of RNA polymerase 2 to enhancers and promoters, especially super-enhancers, to inhibit gene transcription. As such, BET inhibitors may be useful therapeutics for treatment of cancer and inflammatory disease. For example, the small molecule BET inhibitor, JQ1, selectively represses MYC, an important oncogene regulated by a super-enhancer. IFN-γ, a critical cytokine for both innate and adaptive immune responses, is also regulated by a super-enhancer. Here, we show that JQ1 represses IFN-γ expression in TH1 polarized PBMC cultures, CD4+ memory T cells, and NK cells. JQ1 treatment does not reduce activating chromatin marks at the IFNG locus, but displaces RNA polymerase II from the locus. Further, IFN-γ expression recovers in polarized TH1 cultures following removal of JQ1. Our results show that JQ1 abrogates IFN-γ expression, but repression is reversible. Thus, BET inhibitors may disrupt the normal functions of the innate and adaptive immune response.

Published

2019

47. BRAF inhibition sensitizes melanoma cells to α-amanitin via decreased RNA polymerase II assembly.

Author

Frischknecht L, Britschgi C, Galliker P, Christinat Y, Vichalkovski A, Gstaiger M, Kovacs WJ, and Krek W

Subjects

Apoptosis drug effects, Cell Line, Tumor, Humans, Signal Transduction drug effects, Alpha-Amanitin pharmacology, Cell Death drug effects, Melanoma metabolism, Nucleic Acid Synthesis Inhibitors pharmacology, Proto-Oncogene Proteins B-raf antagonists & inhibitors, RNA Polymerase II metabolism

Abstract

Despite the great success of small molecule inhibitors in the treatment of patients with BRAF V600E mutated melanoma, the response to these drugs remains transient and patients eventually relapse within a few months, highlighting the need to develop novel combination therapies based on the understanding of the molecular changes induced by BRAF V600E inhibitors. The acute inhibition of oncogenic signaling can rewire entire cellular signaling pathways and thereby create novel cancer cell vulnerabilities. Here, we demonstrate that inhibition of BRAF V600E oncogenic signaling in melanoma cell lines leads to destabilization of the large subunit of RNA polymerase II POLR2A (polymerase RNA II DNA-directed polypeptide A), thereby preventing its binding to the unconventional prefoldin RPB5 interactor (URI1) chaperone complex and the successful assembly of RNA polymerase II holoenzymes. Furthermore, in melanoma cell lines treated with mitogen-activated protein kinase (MAPK) inhibitors, α-amanitin, a specific and irreversible inhibitor of RNA polymerase II, induced massive apoptosis. Pre-treatment of melanoma cell lines with MAPK inhibitors significantly reduced IC50 values to α-amanitin, creating a state of collateral vulnerability similar to POLR2A hemizygous deletions. Thus, the development of melanoma specific α-amanitin antibody-drug conjugates could represent an interesting therapeutic approach for combination therapies with BRAF V600E inhibitors.

Published

2019

48. Efficacy of the novel CDK7 inhibitor QS1189 in mantle cell lymphoma.

Author

Choi YJ, Kim DH, Yoon DH, Suh C, Choi CM, Lee JC, Hong JY, and Rho JK

Subjects

Adenine analogs & derivatives, Antineoplastic Agents chemistry, Bridged Bicyclo Compounds, Heterocyclic pharmacology, Cell Cycle drug effects, Cell Line, Tumor, Cell Proliferation drug effects, Cell Survival drug effects, Drug Resistance, Neoplasm drug effects, Drug Synergism, Humans, Lymphoma, Mantle-Cell drug therapy, Phosphorylation drug effects, Piperidines, Pyrazoles pharmacology, Pyrimidines pharmacology, RNA Polymerase II chemistry, RNA Polymerase II metabolism, Sulfonamides pharmacology, Triazoles chemistry, Cyclin-Dependent Kinase-Activating Kinase, Antineoplastic Agents chemical synthesis, Antineoplastic Agents pharmacology, Cyclin-Dependent Kinases antagonists & inhibitors, Lymphoma, Mantle-Cell metabolism, Triazoles chemical synthesis, Triazoles pharmacology

Abstract

Mantle cell lymphoma (MCL) is typically an aggressive and rare form of non-Hodgkin lymphoma (NHL) with a poor prognosis despite recent advances in immunochemotherapy and targeted therapeutics against NHL. New therapeutic agents are needed for MCL. In this study, we generated a potent inhibitor of cyclin-dependent kinase 7 (CDK7), designated QS1189, and confirmed its anti-cancer effects towards MCL and other lymphomas. QS1189 was highly selective for CDK7 and showed potent anticancer effects in MCL compared to other targeted therapeutic agents, such as ibrutinib and venetoclax. Consistent with a conventional CDK7 inhibitor, QS1189 treatment significantly decreased phosphorylation of the carboxyl-terminal domain of RNA polymerase II and transcription-associated genes. QS1189 induced cell cycle arrest at the G2/M phase and apoptosis. Interestingly, QS1189 overcame the acquired resistance to venetoclax, which is mediated by Bcl-xL. Similarly, QS1189 showed potent tumour cell growth inhibition of various lymphomas. Thus, CDK7 might be a suitable therapeutic target for inhibiting lymphoma, and QS1189 is a promising therapeutic option for various lymphomas and cells with acquired resistance to targeted therapy.

Published

2019

49. Histone H3 trimethylation at lysine 36 guides m 6 A RNA modification co-transcriptionally.

Author

Huang H, Weng H, Zhou K, Wu T, Zhao BS, Sun M, Chen Z, Deng X, Xiao G, Auer F, Klemm L, Wu H, Zuo Z, Qin X, Dong Y, Zhou Y, Qin H, Tao S, Du J, Liu J, Lu Z, Yin H, Mesquita A, Yuan CL, Hu YC, Sun W, Su R, Dong L, Shen C, Li C, Qing Y, Jiang X, Wu X, Sun M, Guan JL, Qu L, Wei M, Müschen M, Huang G, He C, Yang J, and Chen J

Subjects

Adenosine metabolism, Animals, Cell Differentiation, Cell Line, Embryonic Stem Cells metabolism, Humans, Lysine chemistry, Methylation, Methyltransferases deficiency, Methyltransferases genetics, Methyltransferases metabolism, Mice, RNA Polymerase II metabolism, Transcription Elongation, Genetic, Transcriptome genetics, Adenosine analogs & derivatives, Histones chemistry, Histones metabolism, Lysine metabolism, RNA, Messenger chemistry, RNA, Messenger metabolism, Transcription, Genetic

Abstract

DNA and histone modifications have notable effects on gene expression 1 . Being the most prevalent internal modification in mRNA, the N 6 -methyladenosine (m 6 A) mRNA modification is as an important post-transcriptional mechanism of gene regulation 2-4 and has crucial roles in various normal and pathological processes 5-12 . However, it is unclear how m 6 A is specifically and dynamically deposited in the transcriptome. Here we report that histone H3 trimethylation at Lys36 (H3K36me3), a marker for transcription elongation, guides m 6 A deposition globally. We show that m 6 A modifications are enriched in the vicinity of H3K36me3 peaks, and are reduced globally when cellular H3K36me3 is depleted. Mechanistically, H3K36me3 is recognized and bound directly by METTL14, a crucial component of the m 6 A methyltransferase complex (MTC), which in turn facilitates the binding of the m 6 A MTC to adjacent RNA polymerase II, thereby delivering the m 6 A MTC to actively transcribed nascent RNAs to deposit m 6 A co-transcriptionally. In mouse embryonic stem cells, phenocopying METTL14 knockdown, H3K36me3 depletion also markedly reduces m 6 A abundance transcriptome-wide and in pluripotency transcripts, resulting in increased cell stemness. Collectively, our studies reveal the important roles of H3K36me3 and METTL14 in determining specific and dynamic deposition of m 6 A in mRNA, and uncover another layer of gene expression regulation that involves crosstalk between histone modification and RNA methylation.

Published

2019

50. Recruitment of BRCA1 limits MYCN-driven accumulation of stalled RNA polymerase.

Author

Herold S, Kalb J, Büchel G, Ade CP, Baluapuri A, Xu J, Koster J, Solvie D, Carstensen A, Klotz C, Rodewald S, Schülein-Völk C, Dobbelstein M, Wolf E, Molenaar J, Versteeg R, Walz S, and Eilers M

Subjects

Cell Line, Tumor, Chromatin genetics, Chromatin metabolism, Gene Expression Regulation, Humans, Neuroblastoma genetics, Neuroblastoma pathology, Protein Stability, Thiolester Hydrolases metabolism, BRCA1 Protein metabolism, N-Myc Proto-Oncogene Protein metabolism, RNA Polymerase II metabolism, Transcription Elongation, Genetic

Abstract

MYC is an oncogenic transcription factor that binds globally to active promoters and promotes transcriptional elongation by RNA polymerase II (RNAPII) 1,2 . Deregulated expression of the paralogous protein MYCN drives the development of neuronal and neuroendocrine tumours and is often associated with a particularly poor prognosis 3 . Here we show that, similar to MYC, activation of MYCN in human neuroblastoma cells induces escape of RNAPII from promoters. If the release of RNAPII from transcriptional pause sites (pause release) fails, MYCN recruits BRCA1 to promoter-proximal regions. Recruitment of BRCA1 prevents MYCN-dependent accumulation of stalled RNAPII and enhances transcriptional activation by MYCN. Mechanistically, BRCA1 stabilizes mRNA decapping complexes and enables MYCN to suppress R-loop formation in promoter-proximal regions. Recruitment of BRCA1 requires the ubiquitin-specific protease USP11, which binds specifically to MYCN when MYCN is dephosphorylated at Thr58. USP11, BRCA1 and MYCN stabilize each other on chromatin, preventing proteasomal turnover of MYCN. Because BRCA1 is highly expressed in neuronal progenitor cells during early development 4 and MYC is less efficient than MYCN in recruiting BRCA1, our findings indicate that a cell-lineage-specific stress response enables MYCN-driven tumours to cope with deregulated RNAPII function.

Published

2019