Your search keyword '"Alan C. M. Cheung"' showing total 26 results

1. Structural basis of RNA polymerase inhibition by viral and host factors

Author

Simona Pilotto, Thomas Fouqueau, Natalya Lukoyanova, Carol Sheppard, Soizick Lucas-Staat, Luis Miguel Díaz-Santín, Dorota Matelska, David Prangishvili, Alan C. M. Cheung, and Finn Werner

Subjects

Science

Abstract

Understanding the structural basis for the inhibition of archaeal eukaryotic-like RNA polymerases (RNAPs) during virus infection is of interest for drug design. Here, the authors present the cryo-EM structures of apo Sulfolobus acidocaldarius RNAP and the RNAP complex structures with two regulatory factors, RIP and TFS4 that inhibit transcription and discuss their inhibitory mechanisms.

Published

2021

2. A CDK-regulated chromatin segregase promoting chromosome replication

Author

Erika Chacin, Priyanka Bansal, Karl-Uwe Reusswig, Luis M. Diaz-Santin, Pedro Ortega, Petra Vizjak, Belen Gómez-González, Felix Müller-Planitz, Andrés Aguilera, Boris Pfander, Alan C. M. Cheung, and Christoph F. Kurat

Subjects

Science

Abstract

How cells coordinate chromatin dynamics with the cell cycle machinery to promote genome duplication during S phase is still a matter of study. Here the authors reveal by in vitro reconstitution assays that the AAA + -ATPase containing Yta7 protein in S. cerevisiae promotes chromatin.

Published

2021

3. Structure of the complete, membrane-assembled COPII coat reveals a complex interaction network

Author

Joshua Hutchings, Viktoriya G. Stancheva, Nick R. Brown, Alan C. M. Cheung, Elizabeth A. Miller, and Giulia Zanetti

Subjects

Science

Abstract

Cytosolic coat proteins capture secretory cargo and sculpt membrane carriers for intracellular transport, such as COPII which mediates Endoplasmic Reticulum to Golgi trafficking of thousands of cargoes. Here authors visualise the complete, membrane-assembled COPII coat by cryo-electron tomography and subtomogram averaging, revealing the full network of interactions within and between coat layers.

Published

2021

4. The transcript cleavage factor paralogue TFS4 is a potent RNA polymerase inhibitor

Author

Thomas Fouqueau, Fabian Blombach, Ross Hartman, Alan C. M. Cheung, Mark J. Young, and Finn Werner

Subjects

Science

Abstract

Transcript cleavage factors such as eukaryotic TFIIS assist the resumption of transcription following RNA pol II backtracking. Here the authors find that one of the Sulfolobus solfataricus TFIIS homolog—TFS4—has evolved into a potent RNA polymerase inhibitor potentially involved in antiviral defense.

Published

2017

5. Structural basis of RNA polymerase inhibition by viral and host factors

Author

Thomas Fouqueau, David Prangishvili, Finn Werner, Dorota Matelska, Natalya Lukoyanova, Luis Miguel Díaz-Santín, Alan C. M. Cheung, Simona Pilotto, Soizick Lucas-Staat, Carol Sheppard, University College of London [London] (UCL), Birkbeck College [University of London], Imperial College London, Département de Microbiologie - Department of Microbiology, Institut Pasteur [Paris], Ivane Javakhishvili Tbilisi State University (TSU), University of Bristol [Bristol], Research in the RNAP laboratory at UCL is funded by a Wellcome Investigator Award in Science to FW (WT 207446/Z/17/Z) with the title Mechanisms and Regulation of RNAP transcription., and Institut Pasteur [Paris] (IP)-Université Paris Cité (UPCité)

Subjects

Models, Molecular, Cleavage factor, Time Factors, Archaeal Proteins, Science, [SDV]Life Sciences [q-bio], genetic processes, Allosteric regulation, General Physics and Astronomy, Virus-host interactions, Article, Protein Structure, Secondary, General Biochemistry, Genetics and Molecular Biology, Viral Proteins, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Allosteric Regulation, Transcription (biology), RNA polymerase, Amino Acid Sequence, Binding site, 030304 developmental biology, Host factor, 0303 health sciences, Multidisciplinary, biology, Chemistry, Cryoelectron Microscopy, DNA, DNA-Directed RNA Polymerases, General Chemistry, biology.organism_classification, Viroids, 3. Good health, Cell biology, Sulfolobus, enzymes and coenzymes (carbohydrates), Viruses, health occupations, Nucleic acid, bacteria, Structural biology, Archaeal biology, 030217 neurology & neurosurgery, Protein Binding

Abstract

RNA polymerase inhibition plays an important role in the regulation of transcription in response to environmental changes and in the virus-host relationship. Here we present the high-resolution structures of two such RNAP-inhibitor complexes that provide the structural bases underlying RNAP inhibition in archaea. The Acidianus two-tailed virus encodes the RIP factor that binds inside the DNA-binding channel of RNAP, inhibiting transcription by occlusion of binding sites for nucleic acid and the transcription initiation factor TFB. Infection with the Sulfolobus Turreted Icosahedral Virus induces the expression of the host factor TFS4, which binds in the RNAP funnel similarly to eukaryotic transcript cleavage factors. However, TFS4 allosterically induces a widening of the DNA-binding channel which disrupts trigger loop and bridge helix motifs. Importantly, the conformational changes induced by TFS4 are closely related to inactivated states of RNAP in other domains of life indicating a deep evolutionary conservation of allosteric RNAP inhibition., Understanding the structural basis for the inhibition of archaeal eukaryotic-like RNA polymerases (RNAPs) during virus infection is of interest for drug design. Here, the authors present the cryo-EM structures of apo Sulfolobus acidocaldarius RNAP and the RNAP complex structures with two regulatory factors, RIP and TFS4 that inhibit transcription and discuss their inhibitory mechanisms.

Published

2021

6. A CDK-regulated chromatin segregase promoting chromosome replication

Author

Boris Pfander, Petra Vizjak, Belén Gómez-González, Christoph F. Kurat, Alan C. M. Cheung, E. Chacin, P. Bansal, Karl-Uwe Reusswig, Felix Mueller-Planitz, Luis Miguel Díaz-Santín, Andrés Aguilera, and Pedro A. Ortega

Subjects

Genome instability, chemistry.chemical_compound, Histone, biology, Chemistry, Nucleosome disassembly, biology.protein, Eukaryotic DNA replication, Cell cycle, Chromatin remodeling, DNA, Chromatin, Cell biology

Abstract

The replication of chromosomes during S phase is critical for cellular and organismal function. Replicative stress can result in genome instability, which is a major driver of cancer. Yet how chromatin is made accessible during eukaryotic DNA synthesis is poorly understood.Here, we report the identification of a novel class of chromatin remodeling enzyme, entirely distinct from classical SNF2-ATPase family remodelers. Yta7 is a AAA+-ATPase that assembles into ~ 1 MDa hexameric complexes capable of segregating histones from DNA. Yta7 chromatin segregase promotes chromosome replication both in vivo and in vitro. Biochemical reconstitution experiments using purified proteins revealed that Yta7’s enzymatic activity is regulated by S phase-forms of Cyclin-Dependent Kinase (S-CDK). S-CDK phosphorylation stimulates ATP hydrolysis by Yta7, promoting nucleosome disassembly and chromatin replication.Our results present a novel mechanism of how cells orchestrate chromatin dynamics in co-ordination with the cell cycle machinery to promote genome duplication during S phase.

Published

2020

7. Structure of the complete, membrane-assembled COPII coat reveals a complex interaction network

Author

Nick R. Brown, Elizabeth A. Miller, Viktoriya G. Stancheva, Joshua Hutchings, Giulia Zanetti, and Alan C. M. Cheung

Subjects

Models, Molecular, 0301 basic medicine, Electron Microscope Tomography, Protein Conformation, Vesicular Transport Proteins, Golgi Apparatus, General Physics and Astronomy, Endoplasmic Reticulum, 0302 clinical medicine, ER membrane, Sf9 Cells, Protein Interaction Maps, COPII, 0303 health sciences, Multidisciplinary, Chemistry, Vesicle, Coat complexes, Cell biology, Protein Transport, Membrane, Membrane curvature, symbols, COP-Coated Vesicles, Protein Binding, Coat, Science, Saccharomyces cerevisiae, macromolecular substances, Spodoptera, bcs, Transport carrier, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, symbols.namesake, Interaction network, Animals, Humans, Secretion, 030304 developmental biology, Endoplasmic reticulum, Cryoelectron Microscopy, General Chemistry, Golgi apparatus, 030104 developmental biology, Biophysics, Cryoelectron tomography, 030217 neurology & neurosurgery

Abstract

COPII mediates Endoplasmic Reticulum to Golgi trafficking of thousands of cargoes. Five essential proteins assemble into a two-layer architecture, with the inner layer thought to regulate coat assembly and cargo recruitment, and the outer coat forming cages assumed to scaffold membrane curvature. Here we visualise the complete, membrane-assembled COPII coat by cryo-electron tomography and subtomogram averaging, revealing the full network of interactions within and between coat layers. We demonstrate the physiological importance of these interactions using genetic and biochemical approaches. Mutagenesis reveals that the inner coat alone can provide membrane remodelling function, with organisational input from the outer coat. These functional roles for the inner and outer coats significantly move away from the current paradigm, which posits membrane curvature derives primarily from the outer coat. We suggest these interactions collectively contribute to coat organisation and membrane curvature, providing a structural framework to understand regulatory mechanisms of COPII trafficking and secretion., Cytosolic coat proteins capture secretory cargo and sculpt membrane carriers for intracellular transport, such as COPII which mediates Endoplasmic Reticulum to Golgi trafficking of thousands of cargoes. Here authors visualise the complete, membrane-assembled COPII coat by cryo-electron tomography and subtomogram averaging, revealing the full network of interactions within and between coat layers.

Published

2020

8. Structure of the transcription coactivator SAGA

Author

Christian Dienemann, Alan C. M. Cheung, Patrick Cramer, Henning Urlaub, Alexandra Stützer, and Haibo Wang

Subjects

Models, Molecular, Saccharomyces cerevisiae Proteins, Transcription, Genetic, RNA polymerase II, Saccharomyces cerevisiae, Article, Histones, 03 medical and health sciences, 0302 clinical medicine, Protein Domains, Transcription (biology), Gene Expression Regulation, Fungal, Coactivator, Nucleosome, 030304 developmental biology, Histone Acetyltransferases, 0303 health sciences, Multidisciplinary, biology, Chemistry, Cryoelectron Microscopy, Ubiquitination, Histone acetyltransferase, TATA-Box Binding Protein, Cell biology, Nucleosomes, Protein Subunits, Histone deubiquitination, Transcription Coactivator, biology.protein, Trans-Activators, Transcription Factor TFIID, Transcription factor II D, 030217 neurology & neurosurgery, Protein Binding

Abstract

Gene transcription by RNA polymerase II is regulated by activator proteins that recruit the coactivator complexes SAGA (Spt–Ada–Gcn5–acetyltransferase)1,2 and transcription factor IID (TFIID)2–4. SAGA is required for all regulated transcription5 and is conserved among eukaryotes6. SAGA contains four modules7–9: the activator-binding Tra1 module, the core module, the histone acetyltransferase (HAT) module and the histone deubiquitination (DUB) module. Previous studies provided partial structures10–14, but the structure of the central core module is unknown. Here we present the cryo-electron microscopy structure of SAGA from the yeast Saccharomyces cerevisiae and resolve the core module at 3.3 A resolution. The core module consists of subunits Taf5, Sgf73 and Spt20, and a histone octamer-like fold. The octamer-like fold comprises the heterodimers Taf6–Taf9, Taf10–Spt7 and Taf12–Ada1, and two histone-fold domains in Spt3. Spt3 and the adjacent subunit Spt8 interact with the TATA box-binding protein (TBP)2,7,15–17. The octamer-like fold and its TBP-interacting region are similar in TFIID, whereas Taf5 and the Taf6 HEAT domain adopt distinct conformations. Taf12 and Spt20 form flexible connections to the Tra1 module, whereas Sgf73 tethers the DUB module. Binding of a nucleosome to SAGA displaces the HAT and DUB modules from the core-module surface, allowing the DUB module to bind one face of an ubiquitinated nucleosome. Structural studies on the yeast transcription coactivator complex SAGA (Spt–Ada–Gcn5–acetyltransferase) provide insights into the mechanism of initiation of regulated transcription by this multiprotein complex, which is conserved among eukaryotes.

Published

2019

9. Building transcription complexes

Author

Alan C M, Cheung

Subjects

TATA-Binding Protein Associated Factors, Transcription, Genetic, Mutation, Humans, Transcription Factor TFIID, Models, Biological

Published

2018

10. Share and share alike: the role of Tra1 from the SAGA and NuA4 coactivator complexes

Author

Luis Miguel Díaz-Santín and Alan C. M. Cheung

Subjects

0301 basic medicine, Models, Molecular, Transcriptional Activation, Saccharomyces cerevisiae Proteins, Protein subunit, SAGA, Biochemistry, activator, 03 medical and health sciences, 0302 clinical medicine, Transcription (biology), Coactivator, Genetics, Point-of-View, Biological sciences, Histone Acetyltransferases, Membrane Glycoproteins, Models, Genetic, Chemistry, Eukaryotic transcription, histone acetylation, Tra1, coactivator, Chromatin, Cell biology, 030104 developmental biology, NuA4, Trans-Activators, 030217 neurology & neurosurgery, Biotechnology

Abstract

SAGA and NuA4 are coactivator complexes required for transcription on chromatin. Although they contain different enzymatic and biochemical activities, both contain the large Tra1 subunit. Recent electron microscopy studies have resolved the complete structure of Tra1 and its integration in SAGA/NuA4, providing important insight into Tra1 function.

Published

2018

11. Structure of Ctk3, a subunit of the RNA polymerase II CTD kinase complex, reveals a noncanonical CTD-interacting domain fold

Author

Wolfgang Mühlbacher, Andreas Mayer, Alan C. M. Cheung, Michael Remmert, Johannes Soeding, Mai Sun, Patrick Cramer, and Jürgen Niesser

Subjects

biology, RNA polymerase II, biology.organism_classification, Biochemistry, Molecular biology, Cell biology, Protein structure, Structural Biology, Cyclin-dependent kinase, Transcription (biology), Schizosaccharomyces pombe, Cyclin-dependent kinase complex, biology.protein, Cyclin-dependent kinase 9, CTD, Molecular Biology

Abstract

CTDK-I is a yeast kinase complex that phosphorylates the C-terminal repeat domain (CTD) of RNA polymerase II (Pol II) to promote transcription elongation. CTDK-I contains the cyclin-dependent kinase Ctk1 (homologous to human CDK9/CDK12), the cyclin Ctk2 (human cyclin K), and the yeast-specific subunit Ctk3, which is required for CTDK-I stability and activity. Here we predict that Ctk3 consists of a N-terminal CTD-interacting domain (CID) and a C-terminal three-helix bundle domain. We determine the X-ray crystal structure of the N-terminal domain of the Ctk3 homologue Lsg1 from the fission yeast Schizosaccharomyces pombe at 2.0 A resolution. The structure reveals eight helices arranged into a right-handed superhelical fold that resembles the CID domain present in transcription termination factors Pcf11, Nrd1, and Rtt103. Ctk3 however shows different surface properties and no binding to CTD peptides. Together with the known structure of Ctk1 and Ctk2 homologues, our results lead to a molecular framework for analyzing the structure and function of the CTDK-I complex.

Published

2015

12. RNA polymerase I structure and transcription regulation

Author

Patrick Cramer, Sarah Sainsbury, Dirk Kostrewa, Christoph Engel, and Alan C. M. Cheung

Subjects

0303 health sciences, Multidisciplinary, biology, DNA polymerase, RNA polymerase II, Processivity, Molecular biology, RNA polymerase III, 3. Good health, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, chemistry, Transcription (biology), RNA polymerase, biology.protein, RNA polymerase I, 030217 neurology & neurosurgery, Polymerase, 030304 developmental biology

Abstract

Transcription of ribosomal RNA by RNA polymerase (Pol) I initiates ribosome biogenesis and regulates eukaryotic cell growth. The crystal structure of Pol I from the yeast Saccharomyces cerevisiae at 2.8 A resolution reveals all 14 subunits of the 590-kilodalton enzyme, and shows differences to Pol II. An 'expander' element occupies the DNA template site and stabilizes an expanded active centre cleft with an unwound bridge helix. A 'connector' element invades the cleft of an adjacent polymerase and stabilizes an inactive polymerase dimer. The connector and expander must detach during Pol I activation to enable transcription initiation and cleft contraction by convergent movement of the polymerase 'core' and 'shelf' modules. Conversion between an inactive expanded and an active contracted polymerase state may generally underlie transcription. Regulatory factors can modulate the core-shelf interface that includes a 'composite' active site for RNA chain initiation, elongation, proofreading and termination.

Published

2013

13. Mechanism of Translesion Transcription by RNA Polymerase II and Its Role in Cellular Resistance to DNA Damage

Author

Patrick Cramer, Jeffrey N. Strathern, Alan C. M. Cheung, Mikhail Kashlev, Maria L. Kireeva, Celine Walmacq, Thomas Carell, Chengcheng Ye, Lucyna Lubkowska, and Deanna Gotte

Subjects

DNA Replication, Saccharomyces cerevisiae Proteins, Transcription, Genetic, DNA polymerase, Ultraviolet Rays, RNA polymerase II, Pyrimidine dimer, Saccharomyces cerevisiae, Radiation Tolerance, chemistry.chemical_compound, Transcription (biology), DNA, Fungal, Molecular Biology, biology, DNA replication, Processivity, Cell Biology, Molecular biology, chemistry, Pyrimidine Dimers, biology.protein, RNA Polymerase II, Genome, Fungal, DNA, Nucleotide excision repair, DNA Damage

Abstract

Summary UV-induced cyclobutane pyrimidine dimers (CPDs) in the template DNA strand stall transcription elongation by RNA polymerase II (Pol II). If the nucleotide excision repair machinery does not promptly remove the CPDs, stalled Pol II creates a roadblock for DNA replication and subsequent rounds of transcription. Here we present evidence that Pol II has an intrinsic capacity for translesion synthesis (TLS) that enables bypass of the CPD with or without repair. Translesion synthesis depends on the trigger loop and bridge helix, the two flexible regions of the Pol II subunit Rpb1 that participate in substrate binding, catalysis, and translocation. Substitutions in Rpb1 that promote lesion bypass in vitro increase UV resistance in vivo, and substitutions that inhibit lesion bypass decrease cell survival after UV irradiation. Thus, translesion transcription becomes essential for cell survival upon accumulation of the unrepaired CPD lesions in genomic DNA.

Published

2012

14. Structural basis of initial RNA polymerase II transcription

Author

Sarah Sainsbury, Alan C. M. Cheung, and Patrick Cramer

Subjects

General Immunology and Microbiology, biology, Stereochemistry, viruses, General Neuroscience, RNA, RNA polymerase II, Molecular biology, General Biochemistry, Genetics and Molecular Biology, chemistry.chemical_compound, chemistry, Transcription (biology), Coding strand, RNA polymerase, Nucleoside triphosphate, biology.protein, Binding site, Molecular Biology, DNA

Abstract

During transcription initiation by RNA polymerase (Pol) II, a transient open promoter complex (OC) is converted to an initially transcribing complex (ITC) containing short RNAs, and to a stable elongation complex (EC). We report structures of a Pol II–DNA complex mimicking part of the OC, and of complexes representing minimal ITCs with 2, 4, 5, 6, and 7 nucleotide (nt) RNAs, with and without a non-hydrolyzable nucleoside triphosphate (NTP) in the insertion site +1. The partial OC structure reveals that Pol II positions the melted template strand opposite the active site. The ITC-mimicking structures show that two invariant lysine residues anchor the 3′-proximal phosphate of short RNAs. Short DNA–RNA hybrids adopt a tilted conformation that excludes the +1 template nt from the active site. NTP binding induces complete DNA translocation and the standard hybrid conformation. Conserved NTP contacts indicate a universal mechanism of NTP selection. The essential residue Q1078 in the closed trigger loop binds the NTP 2′-OH group, explaining how the trigger loop couples catalysis to NTP selection, suppressing dNTP binding and DNA synthesis.

Published

2011

15. Architecture of the RNA polymerase-Spt4/5 complex and basis of universal transcription processivity

Author

Sarah Sainsbury, Alan C. M. Cheung, Patrick Cramer, and Fuensanta W. Martinez-Rucobo

Subjects

Genetics, General Immunology and Microbiology, biology, General Neuroscience, genetic processes, RNA, Repressor, RNA polymerase II, Processivity, General Biochemistry, Genetics and Molecular Biology, Cell biology, enzymes and coenzymes (carbohydrates), chemistry.chemical_compound, chemistry, Transcription (biology), RNA polymerase, health occupations, biology.protein, Nucleic acid, bacteria, Molecular Biology, Polymerase

Abstract

Related RNA polymerases (RNAPs) carry out cellular gene transcription in all three kingdoms of life. The universal conservation of the transcription machinery extends to a single RNAP-associated factor, Spt5 (or NusG in bacteria), which renders RNAP processive and may have arisen early to permit evolution of long genes. Spt5 associates with Spt4 to form the Spt4/5 heterodimer. Here, we present the crystal structure of archaeal Spt4/5 bound to the RNAP clamp domain, which forms one side of the RNAP active centre cleft. The structure revealed a conserved Spt5–RNAP interface and enabled modelling of complexes of Spt4/5 counterparts with RNAPs from all kingdoms of life, and of the complete yeast RNAP II elongation complex with bound Spt4/5. The N-terminal NGN domain of Spt5/NusG closes the RNAP active centre cleft to lock nucleic acids and render the elongation complex stable and processive. The C-terminal KOW1 domain is mobile, but its location is restricted to a region between the RNAP clamp and wall above the RNA exit tunnel, where it may interact with RNA and/or other factors.

Published

2011

16. Spt4/5 stimulates transcription elongation through the RNA polymerase clamp coiled-coil motif

Author

Daniel Klose, Finn Werner, Gerke E. Damsma, Patrick Cramer, Dina Grohmann, Andrew J. Martin, Alan C. M. Cheung, Angela Hirtreiter, and Erika Vojnic

Subjects

Models, Molecular, Methanococcus, Transcription, Genetic, Chromosomal Proteins, Non-Histone, Archaeal Proteins, Amino Acid Motifs, Molecular Sequence Data, Crystallography, X-Ray, 03 medical and health sciences, chemistry.chemical_compound, Protein structure, Transcription (biology), RNA polymerase, Genetics, Amino Acid Sequence, Binding site, Conserved Sequence, 030304 developmental biology, Coiled coil, 0303 health sciences, Binding Sites, biology, Nucleic Acid Enzymes, 030302 biochemistry & molecular biology, RNA, Processivity, DNA-Directed RNA Polymerases, biology.organism_classification, Molecular biology, Cell biology, Protein Structure, Tertiary, enzymes and coenzymes (carbohydrates), chemistry, bacteria, Transcriptional Elongation Factors, Hydrophobic and Hydrophilic Interactions

Abstract

Spt5 is the only known RNA polymerase-associated factor that is conserved in all three domains of life. We have solved the structure of the Methanococcus jannaschii Spt4/5 complex by X-ray crystallography, and characterized its function and interaction with the archaeal RNAP in a wholly recombinant in vitro transcription system. Archaeal Spt4 and Spt5 form a stable complex that associates with RNAP independently of the DNA-RNA scaffold of the elongation complex. The association of Spt4/5 with RNAP results in a stimulation of transcription processivity, both in the absence and the presence of the non-template strand. A domain deletion analysis reveals the molecular anatomy of Spt4/5--the Spt5 Nus-G N-terminal (NGN) domain is the effector domain of the complex that both mediates the interaction with RNAP and is essential for its elongation activity. Using a mutagenesis approach, we have identified a hydrophobic pocket on the Spt5 NGN domain as binding site for RNAP, and reciprocally the RNAP clamp coiled-coil motif as binding site for Spt4/5.

Published

2010

17. Nano positioning system reveals the course of upstream and nontemplate DNA within the RNA polymerase II elongation complex

Author

Adam Muschielok, Jens Michaelis, Joanna Andrecka, Barbara Treutlein, Robert Lewis, Patrick Cramer, Maria Angeles Izquierdo Arcusa, and Alan C. M. Cheung

Subjects

Models, Molecular, DNA clamp, Transcription, Genetic, biology, Nucleic Acid Enzymes, DNA polymerase II, Bayes Theorem, RNA polymerase II, DNA, Templates, Genetic, Crystallography, X-Ray, Molecular biology, Upstream and downstream (DNA), chemistry.chemical_compound, chemistry, Coding strand, Transcription preinitiation complex, Fluorescence Resonance Energy Transfer, Genetics, biology.protein, Biophysics, RNA, RNA Polymerase II, Transcription bubble

Abstract

Crystallographic studies of the RNA polymerase II (Pol II) elongation complex (EC) revealed the locations of downstream DNA and the DNA-RNA hybrid, but not the course of the nontemplate DNA strand in the transcription bubble and the upstream DNA duplex. Here we used single-molecule Fluorescence Resonance Energy Transfer (smFRET) experiments to locate nontemplate and upstream DNA with our recently developed Nano Positioning System (NPS). In the resulting complete model of the Pol II EC, separation of the nontemplate from the template strand at position +2 involves interaction with fork loop 2. The nontemplate strand passes loop beta10-beta11 on the Pol II lobe, and then turns to the other side of the cleft above the rudder. The upstream DNA duplex exits at an approximately right angle from the incoming downstream DNA, and emanates from the cleft between the protrusion and clamp. Comparison with published data suggests that the architecture of the complete EC is conserved from bacteria to eukaryotes and that upstream DNA is relocated during the initiation-elongation transition.

Published

2009

18. Structural Basis of Transcription: Mismatch-Specific Fidelity Mechanisms and Paused RNA Polymerase II with Frayed RNA

Author

Jasmin F. Sydow, Florian Brueckner, Patrick Cramer, Elisabeth Lehmann, Alan C. M. Cheung, Dmitry G. Vassylyev, Gerke E. Damsma, and Stefan Dengl

Subjects

Models, Molecular, Transcription, Genetic, Base Pair Mismatch, Uracil Nucleotides, Molecular Sequence Data, RNA polymerase II, Crystallography, X-Ray, RNA polymerase III, chemistry.chemical_compound, Transcription (biology), RNA polymerase, RNA polymerase I, Thymine Nucleotides, Amino Acid Sequence, RNA, Messenger, RNA polymerase II holoenzyme, Molecular Biology, Binding Sites, biology, RNA, Cell Biology, Molecular biology, Protein Structure, Tertiary, Cell biology, chemistry, RNA editing, biology.protein, Nucleic Acid Conformation, RNA Polymerase II

Abstract

We show that RNA polymerase (Pol) II prevents erroneous transcription in vitro with different strategies that depend on the type of DNA,RNA base mismatch. Certain mismatches are efficiently formed but impair RNA extension. Other mismatches allow for RNA extension but are inefficiently formed and efficiently proofread by RNA cleavage. X-ray analysis reveals that a T,U mismatch impairs RNA extension by forming a wobble base pair at the Pol II active center that dissociates the catalytic metal ion and misaligns the RNA30 end. The mismatch can also stabilize a paused state of Pol II with a frayed RNA 30 nucleotide. The frayed nucleotide binds in the Pol II pore either parallel or perpendicular to the DNA-RNA hybrid axis (fraying sites I and II, respectively) and overlaps the nucleoside triphosphate (NTP) site, explaining how it halts transcription during proofreading, before backtracking and RNA cleavage.

Published

2009

19. Structure–function studies of the RNA polymerase II elongation complex

Author

Hubert Kettenberger, Alan C. M. Cheung, Patrick Cramer, Florian Brueckner, Elisabeth Lehmann, Jasmin F. Sydow, Gerke E. Damsma, and Karim-Jean Armache

Subjects

Models, Molecular, Saccharomyces cerevisiae Proteins, Transcription, Genetic, nucleotide-addition cycle, translocation, RNA-dependent RNA polymerase, RNA polymerase II, Crystallography, X-Ray, Models, Biological, Protein Structure, Secondary, RNA polymerase III, transcription factor IIS, Structure-Activity Relationship, Structural Biology, Transcriptional regulation, transcription elongation, RNA polymerase II holoenzyme, DNA-damage recognition, biology, DNA, General Medicine, Processivity, Research Papers, Molecular biology, Protein Structure, Tertiary, Cell biology, Elongation factor, nucleic acids, RNA-dependent RNA polymerase activity, biology.protein, RNA, Transcriptional Elongation Factors, Transcription factor II D

Abstract

X-ray crystallographic and complementary functional studies have contributed significantly to the current understanding of gene transcription. Here, recent structure–function studies on various aspects of the elongation phase of transcription are summarized., RNA polymerase II (Pol II) is the eukaryotic enzyme that is responsible for transcribing all protein-coding genes into messenger RNA (mRNA). The mRNA-transcription cycle can be divided into three stages: initiation, elongation and termination. During elongation, Pol II moves along a DNA template and synthesizes a complementary RNA chain in a processive manner. X-ray structural analysis has proved to be a potent tool for elucidating the mechanism of Pol II elongation. Crystallographic snapshots of different functional states of the Pol II elongation complex (EC) have elucidated mechanistic details of nucleotide addition and Pol II translocation. Further structural studies in combination with in vitro transcription experiments led to a mechanistic understanding of various additional features of the EC, including its inhibition by the fungal toxin α-amanitin, the tunability of the active site by the elongation factor TFIIS, the recognition of DNA lesions and the use of RNA as a template.

Published

2009

20. Complete architecture of the archaeal RNA polymerase open complex from single-molecule FRET and NPS

Author

Dina Grohmann, Julia Nagy, Sarah Schulz, Alan C. M. Cheung, Katherine Smollett, Jens Michaelis, and Finn Werner

Subjects

Archaeal Proteins, General Physics and Astronomy, RNA polymerase II, RNA, Archaeal, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, RNA polymerase, RNA polymerase II holoenzyme, 030304 developmental biology, 0303 health sciences, Multidisciplinary, biology, General transcription factor, DNA-Directed RNA Polymerases, General Chemistry, Molecular biology, enzymes and coenzymes (carbohydrates), DNA, Archaeal, chemistry, Biophysics, biology.protein, Transcription factor II E, Transcription factor II D, Transcription factor II B, 030217 neurology & neurosurgery, Transcription factor II A

Abstract

The molecular architecture of RNAPII-like transcription initiation complexes has been studied for years but its structure has remained opaque due to its conformational flexibility and size. We determined the three-dimensional architecture of the complete open complex (OC) composed of the promoter DNA, TATA box-binding protein (TBP), transcription factors TFB and TFE, and the 12-subunit RNA polymerase (RNAP) from M. jannaschii. By combining single-molecule Förster resonance energy transfer (smFRET) and the Bayesian parameter estimation based Nano-Positioning System (NPS) analysis, we modelled the entire archaeal OC, which elucidates the path of the ntDNA strand and interaction sites of the transcription factors with the RNAP. Compared to models of the eukaryotic OC, the position of the TATA DNA region with TBP and TFB is positioned closer to the surface of the RNAP, likely providing the mechanism by which DNA melting can occur in a minimal factor configuration, without the dedicated translocase/helicase encoding factor TFIIH.

Published

2015

21. A novel intermediate in transcription initiation by human mitochondrial RNA polymerase

Author

Patrick Cramer, Alan C. M. Cheung, Karen Agaronyan, Dmitry Temiakov, Yaroslav I. Morozov, and Michael Anikin

Subjects

Mitochondrial DNA, POLRMT, Mitochondrial Proteins, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, RNA polymerase, Genetics, Transcriptional regulation, Humans, Protein Interaction Domains and Motifs, Promoter Regions, Genetic, Transcription factor, Transcription Initiation, Genetic, Polymerase, 030304 developmental biology, 0303 health sciences, biology, Nucleic Acid Enzymes, Promoter, DNA-Directed RNA Polymerases, TFAM, DNA-Binding Proteins, chemistry, biology.protein, 030217 neurology & neurosurgery, Transcription Factors

Abstract

The mitochondrial genome is transcribed by a single-subunit T7 phage-like RNA polymerase (mtRNAP), structurally unrelated to cellular RNAPs. In higher eukaryotes, mtRNAP requires two transcription factors for efficient initiation—TFAM, a major nucleoid protein, and TFB2M, a transient component of mtRNAP catalytic site. The mechanisms behind assembly of the mitochondrial transcription machinery and its regulation are poorly understood. We isolated and identified a previously unknown human mitochondrial transcription intermediate— a pre-initiation complex that includes mtRNAP, TFAM and promoter DNA. Using protein– protein cross-linking, we demonstrate that human TFAM binds to the N-terminal domain of mtRNAP, which results in bending of the promoter DNA around mtRNAP. The subsequent recruitment of TFB2M induces promoter melting and formation of an open initiation complex. Our data indicate that the pre-initiation complex is likely to be an important target for transcription regulation and provide basis for further structural, biochemical and biophysical studies of mitochondrial transcription.

Published

2014

22. Structure of human mitochondrial RNA polymerase elongation complex

Author

Alan C. M. Cheung, Yaroslav I. Morozov, Karen Agaronyan, Patrick Cramer, Dmitry Temiakov, and Kathrin Schwinghammer

Subjects

Base pair, Protein Conformation, RNA, Mitochondrial, RNA-dependent RNA polymerase, Biology, Crystallography, X-Ray, DNA, Mitochondrial, Article, 03 medical and health sciences, chemistry.chemical_compound, Structural Biology, Transcription (biology), RNA polymerase, RNA polymerase I, Humans, Molecular Biology, Polymerase, 030304 developmental biology, 0303 health sciences, 030302 biochemistry & molecular biology, RNA, DNA-Directed RNA Polymerases, Molecular biology, Cell biology, chemistry, biology.protein, Primase

Abstract

Here we report the crystal structure of the human mitochondrial RNA polymerase (mtRNAP) transcription elongation complex, determined at 2.65-A resolution. The structure reveals a 9-bp hybrid formed between the DNA template and the RNA transcript and one turn of DNA both upstream and downstream of the hybrid. Comparisons with the distantly related RNA polymerase (RNAP) from bacteriophage T7 indicates conserved mechanisms for substrate binding and nucleotide incorporation but also strong mechanistic differences. Whereas T7 RNAP refolds during the transition from initiation to elongation, mtRNAP adopts an intermediary conformation that is capable of elongation without refolding. The intercalating hairpin that melts DNA during T7 RNAP initiation separates RNA from DNA during mtRNAP elongation. Newly synthesized RNA exits toward the pentatricopeptide repeat (PPR) domain, a unique feature of mtRNAP with conserved RNA-recognition motifs.

Published

2013

23. Molecular basis of Rrn3-regulated RNA polymerase I initiation and cell growth

Author

Kristina Lorenzen, Patrick Cramer, Andreas Mayer, Gregor Witte, Stefan Jennebach, Franz Herzog, Karl-Peter Hopfner, Claudia Blattner, Alan C. M. Cheung, Ruedi Aebersold, and Albert J. R. Heck

Subjects

Models, Molecular, RNA polymerase II, 0302 clinical medicine, RRN3 protein, human, Transcriptional regulation, Serine, Promoter Regions, Genetic, chemistry [Pol1 Transcription Initiation Complex Proteins], 0303 health sciences, biology, General transcription factor, metabolism [Serine], metabolism [DNA Polymerase I], cytology [Saccharomyces cerevisiae], chemistry [Saccharomyces cerevisiae Proteins], metabolism [Pol1 Transcription Initiation Complex Proteins], 030220 oncology & carcinogenesis, genetics [Saccharomyces cerevisiae], Transcription factor II B, Pol1 Transcription Initiation Complex Proteins, Protein Binding, Research Paper, Saccharomyces cerevisiae Proteins, Molecular Sequence Data, Saccharomyces cerevisiae, 03 medical and health sciences, POL1 protein, S cerevisiae, ddc:570, genetics [Pol1 Transcription Initiation Complex Proteins], Genetics, Humans, Amino Acid Sequence, Transcription factor, genetics [Saccharomyces cerevisiae Proteins], 030304 developmental biology, Cell Proliferation, metabolism [Saccharomyces cerevisiae], Processivity, metabolism [Saccharomyces cerevisiae Proteins], DNA Polymerase I, Molecular biology, Protein Structure, Tertiary, Transcription preinitiation complex, Mutation, biology.protein, RRN3 protein, S cerevisiae, Protein Multimerization, Sequence Alignment, Developmental Biology

Abstract

Cell growth is regulated during RNA polymerase (Pol) I transcription initiation by the conserved factor Rrn3/TIF-IA in yeast/humans. Here we provide a structure–function analysis of Rrn3 based on a combination of structural biology with in vivo and in vitro functional assays. The Rrn3 crystal structure reveals a unique HEAT repeat fold and a surface serine patch. Phosphorylation of this patch represses human Pol I transcription, and a phospho-mimetic patch mutation prevents Rrn3 binding to Pol I in vitro and reduces cell growth and Pol I gene occupancy in vivo. Cross-linking indicates that Rrn3 binds Pol I between its subcomplexes, AC40/19 and A14/43, which faces the serine patch. The corresponding region of Pol II binds the Mediator head that cooperates with transcription factor (TF) IIB. Consistent with this, the Rrn3-binding factor Rrn7 is predicted to be a TFIIB homolog. This reveals the molecular basis of Rrn3-regulated Pol I initiation and cell growth, and indicates a general architecture of eukaryotic transcription initiation complexes.

Published

2011

24. Structural basis of RNA polymerase II backtracking, arrest and reactivation

Author

Alan C. M. Cheung and Patrick Cramer

Subjects

Models, Molecular, Movement, RNA polymerase II, Saccharomyces cerevisiae, Crystallography, X-Ray, Models, Biological, RNA polymerase III, Structure-Activity Relationship, Catalytic Domain, RNA polymerase II holoenzyme, Multidisciplinary, biology, General transcription factor, Molecular biology, Protein Structure, Tertiary, Enzyme Activation, Protein Subunits, biology.protein, Biocatalysis, Tyrosine, Transcription factor II F, Transcription factor II E, RNA Polymerase II, Transcription factor II D, Protons, Transcriptional Elongation Factors, Transcription factor II B

Abstract

RNA polymerase II (RNA pol II) moves forwards along the DNA strand during gene transcription, synthesizing messenger RNA as it goes. It can also move backwards and stall — a useful property for regulatory purposes or if it hits an obstacle such as a nucleosome. This arrested state is reactivated by transcription factor IIS (TFIIS). Now, the crystal structure of a backtracked yeast RNA pol II complex containing observable backtracked RNA has been determined at 3.3 A resolution, as well as the structure of a backtracked complex containing TFIIS. The structures reveal possible mechanisms of transcriptional stalling and transcription reactivation. During gene transcription, RNA polymerase (Pol) II moves forward along DNA and synthesizes mRNA. However, Pol II can also move backwards and stall, which is important for regulatory purposes or when the polymerase hits an obstacle such as a nucleosome. This arrested state is reactivated by the transcription factor TFIIS. Here, a crystal structure is presented of a backtracked yeast Pol II complex in which the backtracked RNA can be observed, plus a structure of a backtracked complex that contains TFIIS. A model is presented for Pol II backtracking, arrest and reactivation during transcription elongation. During gene transcription, RNA polymerase (Pol) II moves forwards along DNA and synthesizes messenger RNA. However, at certain DNA sequences, Pol II moves backwards, and such backtracking can arrest transcription. Arrested Pol II is reactivated by transcription factor IIS (TFIIS), which induces RNA cleavage that is required for cell viability1. Pol II arrest and reactivation are involved in transcription through nucleosomes2,3 and in promoter-proximal gene regulation4,5,6. Here we present X-ray structures at 3.3 A resolution of an arrested Saccharomyces cerevisiae Pol II complex with DNA and RNA, and of a reactivation intermediate that additionally contains TFIIS. In the arrested complex, eight nucleotides of backtracked RNA bind a conserved ‘backtrack site’ in the Pol II pore and funnel, trapping the active centre trigger loop and inhibiting mRNA elongation. In the reactivation intermediate, TFIIS locks the trigger loop away from backtracked RNA, displaces RNA from the backtrack site, and complements the polymerase active site with a basic and two acidic residues that may catalyse proton transfers during RNA cleavage. The active site is demarcated from the backtrack site by a ‘gating tyrosine’ residue that probably delimits backtracking. These results establish the structural basis of Pol II backtracking, arrest and reactivation, and provide a framework for analysing gene regulation during transcription elongation.

Published

2011

25. Artificial Neural Networks for Reducing the Dimensionality of Gene Expression Data

Author

Christophe Vercellone, Ajit Narayanan, Jonas Gamalielsson, Edward Keedwell, and Alan C. M. Cheung

Subjects

Artificial neural network, Computer science, business.industry, Gene expression, Artificial intelligence, Machine learning, computer.software_genre, business, computer, Curse of dimensionality

Published

2006

26. A Movie of RNA Polymerase II Transcription

Author

Alan C. M. Cheung and Patrick Cramer

Subjects

0303 health sciences, Bacteria, Transcription, Genetic, Biochemistry, Genetics and Molecular Biology(all), Motion Pictures, Fungi, RNA polymerase II, Computational biology, Biology, 010402 general chemistry, 01 natural sciences, Archaea, General Biochemistry, Genetics and Molecular Biology, 0104 chemical sciences, 03 medical and health sciences, Transcription (biology), Teaching tool, biology.protein, Proofreading, Humans, RNA Polymerase II, 030304 developmental biology, Transcription Factors

Abstract

We provide here a molecular movie that captures key aspects of RNA polymerase II initiation and elongation. To create the movie, we combined structural snapshots of the initiation-elongation transition and of elongation, including nucleotide addition, translocation, pausing, proofreading, backtracking, arrest, reactivation, and inhibition. The movie reveals open questions about the mechanism of transcription and provides a useful teaching tool.