Structural studies of Mot1 and NC2 in transcription initiation process

Regulation of protein–nucleic acid interactions plays a key role in various cellular processes. The SNF2/SWI2 protein family forms a large and diverse class of proteins and multiprotein assemblies, which use energy derived from ATP hydrolysis to disrupt or modify protein-DNA interactions. They possess a conserved helicase-like domain accompanied by protein-specific targeting and regulation regions. The SNF2/SWI2 family member Mot1 (Modifier of transcription 1, also known as BTAF1) is a single polypeptide ATP-dependent remodeler. Mot1 acts directly on TBP (TATA-box binding protein) regulating RNA polymerase II preinitiation complex formation in the first stages. Global distribution of TBP on promoter regions is also modulated by NC2 (Negative Cofactor 2). It has been suggested that Mot1 and NC2 can co occupy the same promoter sites influencing the assembly of the transcription machinery simultaneously. Our understanding of the molecular mechanism of SWI2/SNF2 family ATPases is very limited. Previously, we have reported the crystal structure of the complex of Encephalitozoon cuniculi N terminal domain of Mot1 (Mot1NTD) with its substrate, TBP [1]. Here we present the crystal structure of the TBP NC2 Mot1NTD complex bound to a promoter DNA fragment at 3.9Å resolution. In our studies we have applied a combined structural biology approach using crystallography, electron microscopy reconstructions and chemical cross-linking. We probed the conformational changes of the complex during the ATP hydrolysis cycle and unveiled the structural basis of the Mot1–NC2 interplay. Our findings greatly contribute not only to our limited understanding of Mot1 action, but all SNF2/SWI2 family remodeling enzymes.

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A TBP-independent mechanism for RNA Polymerase II transcription

10.1101/2021.03.28.437425 ◽

2021 ◽

Author(s):

James Z.J. Kwan ◽

Thomas F. Nguyen ◽

Marek A. Budzyński ◽

Jieying Cui ◽

Rachel M. Price ◽

...

Keyword(s):

Rna Polymerase ◽

Rna Polymerase Ii ◽

Transcription Initiation ◽

Rna Polymerase Iii ◽

Embryonic Stem ◽

Promoter Regions ◽

Pol Ii ◽

Promoter Dna ◽

Tata Box Binding Protein

AbstractTranscription by RNA Polymerase II (Pol II) is initiated by the hierarchical assembly of the Pre-Initiation Complex onto promoter DNA. Decades of in vitro and yeast research have shown that the TATA-box binding protein (TBP) is essential to Pol II initiation by triggering the binding of other general transcription factors, and ensuring proper Pol II loading. Here, we report instead that acute depletion of TBP in mouse embryonic stem cells (mESCs) has no global effect on ongoing Pol II transcription. Surprisingly, Pol II transcriptional induction through the Heat Shock Response or cellular differentiation also occurs normally in the absence of TBP. In contrast, acute TBP depletion severely impairs initiation by RNA Polymerase III. Lastly, we show that a metazoan-specific paralog of TBP is expressed in mESCs and that it binds to promoter regions of active Pol II genes even in the absence of TBP. Taken together, our findings reveal an unexplored TBP-independent process in mESCs that points to a diversity in Pol II transcription initiation mechanisms.

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Structural basis for transcription initiation by bacterial ECF σ factors

10.1101/534826 ◽

2019 ◽

Author(s):

Lingting Li ◽

Chengli Fang ◽

Ningning Zhuang ◽

Tiantian Wang ◽

Yu Zhang

Keyword(s):

Crystal Structure ◽

Transcription Initiation ◽

Structural Basis ◽

Specific Gene ◽

Bacterial Rna ◽

Promoter Recognition ◽

Σ Factor ◽

Transcription Initiation Complex ◽

Promoter Dna ◽

Context Specific

AbstractBacterial RNA polymerase employs extra-cytoplasmic function (ECF) σ factors to regulate context-specific gene expression programs. Despite being the most abundant and divergent σ factor class, the structural basis of ECF σ factor-mediated transcription initiation remains unknown. Here, we determine a crystal structure of Mycobacterium tuberculosis (Mtb) RNAP holoenzyme comprising an RNAP core enzyme and the ECF σ factor σH (σH-RNAP) at 2.7 Å, and solve another crystal structure of a transcription initiation complex of Mtb σH-RNAP (σH-RPo) comprising promoter DNA and an RNA primer at 2.8 Å. The two structures together reveal the interactions between σH and RNAP that are essential for σH-RNAP holoenzyme assembly as well as the interactions between σH-RNAP and promoter DNA responsible for stringent promoter recognition and for promoter unwinding. Our study establishes that ECF σ factors and primary σ factors employ distinct mechanisms for promoter recognition and for promoter unwinding.

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E. coli TraR allosterically regulates transcription initiation by altering RNA polymerase conformation

eLife ◽

10.7554/elife.49375 ◽

2019 ◽

Vol 8 ◽

Cited By ~ 14

Author(s):

James Chen ◽

Saumya Gopalkrishnan ◽

Courtney Chiu ◽

Albert Y Chen ◽

Elizabeth A Campbell ◽

...

Keyword(s):

Rna Polymerase ◽

Conformational Changes ◽

Transcription Initiation ◽

Structural Changes ◽

Structural Basis ◽

E Coli ◽

Bacterial Proteins ◽

Promoter Complex ◽

Promoter Dna ◽

Induced Changes

TraR and its homolog DksA are bacterial proteins that regulate transcription initiation by binding directly to RNA polymerase (RNAP) rather than to promoter DNA. Effects of TraR mimic the combined effects of DksA and its cofactor ppGpp, but the structural basis for regulation by these factors remains unclear. Here, we use cryo-electron microscopy to determine structures of Escherichia coli RNAP, with or without TraR, and of an RNAP-promoter complex. TraR binding induced RNAP conformational changes not seen in previous crystallographic analyses, and a quantitative analysis revealed TraR-induced changes in RNAP conformational heterogeneity. These changes involve mobile regions of RNAP affecting promoter DNA interactions, including the βlobe, the clamp, the bridge helix, and several lineage-specific insertions. Using mutational approaches, we show that these structural changes, as well as effects on σ70 region 1.1, are critical for transcription activation or inhibition, depending on the kinetic features of regulated promoters.

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Transcription initiation at a consensus bacterial promoter proceeds via a 'bind-unwind-load-and-lock' mechanism

eLife ◽

10.7554/elife.70090 ◽

2021 ◽

Vol 10 ◽

Author(s):

Abhishek Mazumder ◽

Richard H Ebright ◽

Achillefs Kapanidis

Keyword(s):

Single Molecule ◽

Conformational Changes ◽

Transcription Initiation ◽

Core Promoter ◽

Resonance Energy Transfer ◽

Resonance Energy ◽

Extensive Study ◽

Active Centre ◽

Transient Nature ◽

Promoter Dna

Transcription initiation starts with unwinding of promoter DNA by RNA polymerase (RNAP) to form a catalytically competent RNAP-promoter complex (RPO). Despite extensive study, the mechanism of promoter unwinding has remained unclear, in part due to the transient nature of intermediates on path to RPo. Here, using single-molecule unwinding-induced fluorescence enhancement to monitor promoter unwinding, and single-molecule fluorescence resonance energy transfer to monitor RNAP clamp conformation, we analyze RPo formation at a consensus bacterial core promoter. We find that the RNAP clamp is closed during promoter binding, remains closed during promoter unwinding, and then closes further, locking the unwound DNA in the RNAP active-centre cleft. Our work defines a new, 'bind-unwind-load-and-lock' model for the series of conformational changes occurring during promoter unwinding at a consensus bacterial promoter and provides the tools needed to examine the process in other organisms and at other promoters.

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Structural basis of transcription initiation by RNA polymerase II

Nature Reviews Molecular Cell Biology ◽

10.1038/nrm3952 ◽

2015 ◽

Vol 16 (3) ◽

pp. 129-143 ◽

Cited By ~ 200

Author(s):

Sarah Sainsbury ◽

Carrie Bernecky ◽

Patrick Cramer

Keyword(s):

Rna Polymerase ◽

Rna Polymerase Ii ◽

Transcription Initiation ◽

Structural Basis

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Initiation by RNA polymerase II and formation of runoff transcripts containing unblocked and unmethylated 5' termini

Molecular and Cellular Biology ◽

10.1128/mcb.3.12.2172-2179.1983 ◽

1983 ◽

Vol 3 (12) ◽

pp. 2172-2179

Author(s):

H Ernst ◽

W Filipowicz ◽

A J Shatkin

Keyword(s):

Rna Polymerase ◽

Rna Polymerase Ii ◽

Atp Hydrolysis ◽

Beta Globin ◽

Whole Cell ◽

Whole Cell Lysate ◽

Cell Lysate ◽

Promoter Dna ◽

Gamma S ◽

Made In

Transcription of cloned adenovirus, beta-globin, and retrovirus long terminal repeat DNAs in HeLa whole-cell lysate was inhibited by S-adenosylhomocysteine. However, full-length 1.7-kilobase transcripts made on adenovirus 2 late promoter DNA contained 5'-terminal GpppA, consistent with specific initiation and runoff synthesis in the absence of product methylation. Formation of runoff transcripts including retrovirus RNAs that normally contain 5'-m7GpppGmpC was not decreased by replacing GTP with non-hydrolyzable analogs, and Rous-associated virus-2 runoff products made in the presence of GTP-gamma-S contained 5'-terminal gamma-S-pppGpC. The results indicate that capping and specific transcript synthesis by RNA polymerase II are not obligatorily linked in HeLa whole-cell lysate. Accurate initiation is dependent on ATP hydrolysis, and in contrast to GTP, replacement of ATP by 5'-adenylyl-imidodiphosphate blocked specific initiation of transcripts that start with either GTP (Rous-associated virus-2, Rous-associated virus-0) or ATP (beta-globin, adenovirus).

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Direct binding of TFEα opens DNA binding cleft of RNA polymerase

Nature Communications ◽

10.1038/s41467-020-19998-x ◽

2020 ◽

Vol 11 (1) ◽

Author(s):

Sung-Hoon Jun ◽

Jaekyung Hyun ◽

Jeong Seok Cha ◽

Hoyoung Kim ◽

Michael S. Bartlett ◽

...

Keyword(s):

Dna Binding ◽

Rna Polymerase ◽

Transcription Initiation ◽

Structural Basis ◽

Transcription Bubble ◽

Cryo Electron Microscopy ◽

Direct Binding ◽

Binding Cleft ◽

Promoter Dna ◽

Winged Helix Domain

AbstractOpening of the DNA binding cleft of cellular RNA polymerase (RNAP) is necessary for transcription initiation but the underlying molecular mechanism is not known. Here, we report on the cryo-electron microscopy structures of the RNAP, RNAP-TFEα binary, and RNAP-TFEα-promoter DNA ternary complexes from archaea, Thermococcus kodakarensis (Tko). The structures reveal that TFEα bridges the RNAP clamp and stalk domains to open the DNA binding cleft. Positioning of promoter DNA into the cleft closes it while maintaining the TFEα interactions with the RNAP mobile modules. The structures and photo-crosslinking results also suggest that the conserved aromatic residue in the extended winged-helix domain of TFEα interacts with promoter DNA to stabilize the transcription bubble. This study provides a structural basis for the functions of TFEα and elucidates the mechanism by which the DNA binding cleft is opened during transcription initiation in the stalk-containing RNAPs, including archaeal and eukaryotic RNAPs.

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The cryoelectron microscopy structure of the human CDK-activating kinase

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.2009627117 ◽

2020 ◽

Vol 117 (37) ◽

pp. 22849-22857 ◽

Cited By ~ 2

Author(s):

Basil J. Greber ◽

Juan M. Perez-Bertoldi ◽

Kif Lim ◽

Anthony T. Iavarone ◽

Daniel B. Toso ◽

...

Keyword(s):

Cell Cycle ◽

Rna Polymerase Ii ◽

Transcription Initiation ◽

Rational Design ◽

Control Cell ◽

3D Structure ◽

Structural Basis ◽

Pol Ii ◽

Insight Into ◽

Cdk Activating Kinase

The human CDK-activating kinase (CAK), a complex composed of cyclin-dependent kinase (CDK) 7, cyclin H, and MAT1, is a critical regulator of transcription initiation and the cell cycle. It acts by phosphorylating the C-terminal heptapeptide repeat domain of the RNA polymerase II (Pol II) subunit RPB1, which is an important regulatory event in transcription initiation by Pol II, and it phosphorylates the regulatory T-loop of CDKs that control cell cycle progression. Here, we have determined the three-dimensional (3D) structure of the catalytic module of human CAK, revealing the structural basis of its assembly and providing insight into CDK7 activation in this context. The unique third component of the complex, MAT1, substantially extends the interaction interface between CDK7 and cyclin H, explaining its role as a CAK assembly factor, and it forms interactions with the CDK7 T-loop, which may contribute to enhancing CAK activity. We have also determined the structure of the CAK in complex with the covalently bound inhibitor THZ1 in order to provide insight into the binding of inhibitors at the CDK7 active site and to aid in the rational design of therapeutic compounds.

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Structural basis for DEAH-helicase activation by G-patch proteins

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1913880117 ◽

2020 ◽

Vol 117 (13) ◽

pp. 7159-7170 ◽

Cited By ~ 2

Author(s):

Michael K. Studer ◽

Lazar Ivanović ◽

Marco E. Weber ◽

Sabrina Marti ◽

Stefanie Jonas

Keyword(s):

Conformational Changes ◽

Ribosome Biogenesis ◽

Rna Binding ◽

Atp Hydrolysis ◽

Protein Complexes ◽

Adenosine Diphosphate ◽

Structural Basis ◽

Rna Helicases ◽

Catalytic Core ◽

Terminal Domains

RNA helicases of the DEAH/RHA family are involved in many essential cellular processes, such as splicing or ribosome biogenesis, where they remodel large RNA–protein complexes to facilitate transitions to the next intermediate. DEAH helicases couple adenosine triphosphate (ATP) hydrolysis to conformational changes of their catalytic core. This movement results in translocation along RNA, which is held in place by auxiliary C-terminal domains. The activity of DEAH proteins is strongly enhanced by the large and diverse class of G-patch activators. Despite their central roles in RNA metabolism, insight into the molecular basis of G-patch–mediated helicase activation is missing. Here, we have solved the structure of human helicase DHX15/Prp43, which has a dual role in splicing and ribosome assembly, in complex with the G-patch motif of the ribosome biogenesis factor NKRF. The G-patch motif binds in an extended conformation across the helicase surface. It tethers the catalytic core to the flexibly attached C-terminal domains, thereby fixing a conformation that is compatible with RNA binding. Structures in the presence or absence of adenosine diphosphate (ADP) suggest that motions of the catalytic core, which are required for ATP binding, are still permitted. Concomitantly, RNA affinity, helicase, and ATPase activity of DHX15 are increased when G-patch is bound. Mutations that detach one end of the tether but maintain overall binding severely impair this enhancement. Collectively, our data suggest that the G-patch motif acts like a flexible brace between dynamic portions of DHX15 that restricts excessive domain motions but maintains sufficient flexibility for catalysis.

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Structural basis of the transactivation deficiency of the human PPARγ F360L mutant associated with familial partial lipodystrophy

Acta Crystallographica Section D Biological Crystallography ◽

10.1107/s1399004714009638 ◽

2014 ◽

Vol 70 (7) ◽

pp. 1965-1976 ◽

Cited By ~ 9

Author(s):

Clorinda Lori ◽

Alessandra Pasquo ◽

Roberta Montanari ◽

Davide Capelli ◽

Valerio Consalvi ◽

...

Keyword(s):

Crystal Structure ◽

Conformational Changes ◽

Partial Agonist ◽

Salt Bridge ◽

Van Der Waals Interactions ◽

Structural Basis ◽

Wild Type ◽

Partial Lipodystrophy ◽

X Ray ◽

Familial Partial Lipodystrophy

The peroxisome proliferator-activated receptors (PPARs) are transcription factors that regulate glucose and lipid metabolism. The role of PPARs in several chronic diseases such as type 2 diabetes, obesity and atherosclerosis is well known and, for this reason, they are the targets of antidiabetic and hypolipidaemic drugs. In the last decade, some rare mutations in human PPARγ that might be associated with partial lipodystrophy, dyslipidaemia, insulin resistance and colon cancer have emerged. In particular, the F360L mutant of PPARγ (PPARγ2 residue 388), which is associated with familial partial lipodystrophy, significantly decreases basal transcriptional activity and impairs stimulation by synthetic ligands. To date, the structural reason for this defective behaviour is unclear. Therefore, the crystal structure of PPARγ F360L together with the partial agonist LT175 has been solved and the mutant has been characterized by circular-dichroism spectroscopy (CD) in order to compare its thermal stability with that of the wild-type receptor. The X-ray analysis showed that the mutation induces dramatic conformational changes in the C-terminal part of the receptor ligand-binding domain (LBD) owing to the loss of van der Waals interactions made by the Phe360 residue in the wild type and an important salt bridge made by Arg357, with consequent rearrangement of loop 11/12 and the activation function helix 12 (H12). The increased mobility of H12 makes the binding of co-activators in the hydrophobic cleft less efficient, thereby markedly lowering the transactivation activity. The spectroscopic analysis in solution and molecular-dynamics (MD) simulations provided results which were in agreement and consistent with the mutant conformational changes observed by X-ray analysis. Moreover, to evaluate the importance of the salt bridge made by Arg357, the crystal structure of the PPARγ R357A mutant in complex with the agonist rosiglitazone has been solved.

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