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1.
iScience ; 27(8): 110421, 2024 Aug 16.
Artículo en Inglés | MEDLINE | ID: mdl-39108719

RESUMEN

The Streptomyces antibiotic regulatory proteins (SARPs) are ubiquitously distributed transcription activators in Streptomyces and control antibiotics biosynthesis and morphological differentiation. However, the molecular mechanism behind SARP-dependent transcription initiation remains elusive. We here solve the cryo-EM structure of an AfsR-loading RNA polymerase (RNAP)-promoter intermediate complex (AfsR-RPi) including the Streptomyces coelicolor RNAP, a large SARP member AfsR, and its target promoter DNA that retains the upstream portion straight. The structure reveals that one dimeric N-terminal AfsR-SARP domain (AfsR-SARP) specifically engages with the same face of the AfsR-binding sites by the conserved DNA-binding domains (DBDs), replacing σHrdBR4 to bind the suboptimal -35 element, and shortens the spacer between the -10 and -35 elements. Notably, the AfsR-SARPs also recruit RNAP through extensively interacting with its conserved domains (ß flap, σHrdBR4, and αCTD). Thus, these macromolecular snapshots support a general model and provide valuable clues for SARP-dependent transcription activation in Streptomyces.

2.
Protein Sci ; 33(6): e5012, 2024 Jun.
Artículo en Inglés | MEDLINE | ID: mdl-38723180

RESUMEN

The enormous LysR-type transcriptional regulators (LTTRs), which are diversely distributed amongst prokaryotes, play crucial roles in transcription regulation of genes involved in basic metabolic pathways, virulence and stress resistance. However, the precise transcription activation mechanism of these genes by LTTRs remains to be explored. Here, we determine the cryo-EM structure of a LTTR-dependent transcription activation complex comprising of Escherichia coli RNA polymerase (RNAP), an essential LTTR protein GcvA and its cognate promoter DNA. Structural analysis shows two N-terminal DNA binding domains of GcvA (GcvA_DBD) dimerize and engage the GcvA activation binding sites, presenting the -35 element for specific recognition with the conserved σ70R4. In particular, the versatile C-terminal domain of α subunit of RNAP directly interconnects with GcvA_DBD, σ70R4 and promoter DNA, providing more interfaces for stabilizing the complex. Moreover, molecular docking supports glycine as one potential inducer of GcvA, and single molecule photobleaching experiments kinetically visualize the occurrence of tetrameric GcvA-engaged transcription activation complex as suggested for the other LTTR homologs. Thus, a general model for tetrameric LTTR-dependent transcription activation is proposed. These findings will provide new structural and functional insights into transcription activation of the essential LTTRs.


Asunto(s)
ARN Polimerasas Dirigidas por ADN , Escherichia coli , Activación Transcripcional , Escherichia coli/genética , Escherichia coli/metabolismo , ARN Polimerasas Dirigidas por ADN/metabolismo , ARN Polimerasas Dirigidas por ADN/química , ARN Polimerasas Dirigidas por ADN/genética , Proteínas Bacterianas/química , Proteínas Bacterianas/metabolismo , Proteínas Bacterianas/genética , Regiones Promotoras Genéticas , Microscopía por Crioelectrón , Proteínas de Escherichia coli/química , Proteínas de Escherichia coli/metabolismo , Proteínas de Escherichia coli/genética , Factores de Transcripción/química , Factores de Transcripción/metabolismo , Factores de Transcripción/genética , Modelos Moleculares , Simulación del Acoplamiento Molecular , Regulación Bacteriana de la Expresión Génica , Multimerización de Proteína , Sitios de Unión
3.
Structure ; 31(8): 968-974.e3, 2023 08 03.
Artículo en Inglés | MEDLINE | ID: mdl-37269829

RESUMEN

The CII protein of bacteriophage λ activates transcription from the phage promoters PRE, PI, and PAQ by binding to two direct repeats that straddle the promoter -35 element. Although genetic, biochemical, and structural studies have elucidated many aspects of λCII-mediated transcription activation, no precise structure of the transcription machinery in the process is available. Here, we report a 3.1-Å cryo-electron microscopy (cryo-EM) structure of an intact λCII-dependent transcription activation complex (TAC-λCII), which comprises λCII, E. coli RNAP-σ70 holoenzyme, and the phage promoter PRE. The structure reveals the interactions between λCII and the direct repeats responsible for promoter specificity and the interactions between λCII and RNAP α subunit C-terminal domain responsible for transcription activation. We also determined a 3.4-Å cryo-EM structure of an RNAP-promoter open complex (RPo-PRE) from the same dataset. Structural comparison between TAC-λCII and RPo-PRE provides new insights into λCII-dependent transcription activation.


Asunto(s)
Proteínas de Escherichia coli , Escherichia coli , Escherichia coli/metabolismo , Activación Transcripcional , Microscopía por Crioelectrón , ARN Polimerasas Dirigidas por ADN/química , Proteínas de Escherichia coli/química , Bacteriófago lambda/genética , Bacteriófago lambda/metabolismo , Transcripción Genética
4.
Proc Natl Acad Sci U S A ; 120(22): e2300282120, 2023 05 30.
Artículo en Inglés | MEDLINE | ID: mdl-37216560

RESUMEN

In actinobacteria, an OmpR/PhoB subfamily protein called GlnR acts as an orphan response regulator and globally coordinates the expression of genes responsible for nitrogen, carbon, and phosphate metabolism in actinobacteria. Although many researchers have attempted to elucidate the mechanisms of GlnR-dependent transcription activation, progress is impeded by lacking of an overall structure of GlnR-dependent transcription activation complex (GlnR-TAC). Here, we report a co-crystal structure of the C-terminal DNA-binding domain of GlnR (GlnR_DBD) in complex with its regulatory cis-element DNA and a cryo-EM structure of GlnR-TAC which comprises Mycobacterium tuberculosis RNA polymerase, GlnR, and a promoter containing four well-characterized conserved GlnR binding sites. These structures illustrate how four GlnR protomers coordinate to engage promoter DNA in a head-to-tail manner, with four N-terminal receiver domains of GlnR (GlnR-RECs) bridging GlnR_DBDs and the RNAP core enzyme. Structural analysis also unravels that GlnR-TAC is stabilized by complex protein-protein interactions between GlnR and the conserved ß flap, σAR4, αCTD, and αNTD domains of RNAP, which are further confirmed by our biochemical assays. Taken together, these results reveal a global transcription activation mechanism for the master regulator GlnR and other OmpR/PhoB subfamily proteins and present a unique mode of bacterial transcription regulation.


Asunto(s)
Actinobacteria , Actinobacteria/genética , Actinobacteria/metabolismo , Activación Transcripcional/genética , Proteínas Bacterianas/metabolismo , Transactivadores/metabolismo , Regiones Promotoras Genéticas/genética , Regulación Bacteriana de la Expresión Génica
5.
Proc Natl Acad Sci U S A ; 120(2): e2217493120, 2023 01 10.
Artículo en Inglés | MEDLINE | ID: mdl-36598938

RESUMEN

In response to DNA damage, bacterial RecA protein forms filaments with the assistance of DinI protein. The RecA filaments stimulate the autocleavage of LexA, the repressor of more than 50 SOS genes, and activate the SOS response. During the late phase of SOS response, the RecA filaments stimulate the autocleavage of UmuD and λ repressor CI, leading to mutagenic repair and lytic cycle, respectively. Here, we determined the cryo-electron microscopy structures of Escherichia coli RecA filaments in complex with DinI, LexA, UmuD, and λCI by helical reconstruction. The structures reveal that LexA and UmuD dimers bind in the filament groove and cleave in an intramolecular and an intermolecular manner, respectively, while λCI binds deeply in the filament groove as a monomer. Despite their distinct folds and oligomeric states, all RecA filament binders recognize the same conserved protein features in the filament groove. The SOS response in bacteria can lead to mutagenesis and antimicrobial resistance, and our study paves the way for rational drug design targeting the bacterial SOS response.


Asunto(s)
Proteínas de Escherichia coli , Proteínas de Escherichia coli/genética , Proteínas de Escherichia coli/metabolismo , Proteínas Bacterianas/genética , Proteínas Bacterianas/metabolismo , Respuesta SOS en Genética , Microscopía por Crioelectrón , ADN Polimerasa Dirigida por ADN/metabolismo , Escherichia coli/genética , Escherichia coli/metabolismo , Rec A Recombinasas/metabolismo
6.
Nature ; 613(7945): 783-789, 2023 01.
Artículo en Inglés | MEDLINE | ID: mdl-36631609

RESUMEN

Efficient and accurate termination is required for gene transcription in all living organisms1,2. Cellular RNA polymerases in both bacteria and eukaryotes can terminate their transcription through a factor-independent termination pathway3,4-called intrinsic termination transcription in bacteria-in which RNA polymerase recognizes terminator sequences, stops nucleotide addition and releases nascent RNA spontaneously. Here we report a set of single-particle cryo-electron microscopy structures of Escherichia coli transcription intrinsic termination complexes representing key intermediate states of the event. The structures show how RNA polymerase pauses at terminator sequences, how the terminator RNA hairpin folds inside RNA polymerase, and how RNA polymerase rewinds the transcription bubble to release RNA and then DNA. These macromolecular snapshots define a structural mechanism for bacterial intrinsic termination and a pathway for RNA release and DNA collapse that is relevant for factor-independent termination by all RNA polymerases.


Asunto(s)
ADN Bacteriano , ARN Polimerasas Dirigidas por ADN , Escherichia coli , ARN Bacteriano , Terminación de la Transcripción Genética , Microscopía por Crioelectrón , ARN Polimerasas Dirigidas por ADN/química , ARN Polimerasas Dirigidas por ADN/metabolismo , ARN Polimerasas Dirigidas por ADN/ultraestructura , Escherichia coli/química , Escherichia coli/genética , Escherichia coli/metabolismo , Escherichia coli/ultraestructura , ARN Bacteriano/química , ARN Bacteriano/genética , ARN Bacteriano/metabolismo , ARN Bacteriano/ultraestructura , Regiones Terminadoras Genéticas/genética , ADN Bacteriano/química , ADN Bacteriano/genética , ADN Bacteriano/metabolismo , ADN Bacteriano/ultraestructura
7.
Nucleic Acids Res ; 50(19): 11359-11373, 2022 10 28.
Artículo en Inglés | MEDLINE | ID: mdl-36243985

RESUMEN

Transcription activation is established through extensive protein-protein and protein-DNA interactions that allow an activator to engage and remodel RNA polymerase. SoxS, a global transcription activator, diversely regulates subsets of stress response genes with different promoters, but the detailed SoxS-dependent transcription initiation mechanisms remain obscure. Here, we report cryo-EM structures of three SoxS-dependent transcription activation complexes (SoxS-TACI, SoxS-TACII and SoxS-TACIII) comprising of Escherichia coli RNA polymerase (RNAP), SoxS protein and three representative classes of SoxS-regulated promoters. The structures reveal that SoxS monomer orchestrates transcription initiation through specific interactions with the promoter DNA and different conserved domains of RNAP. In particular, SoxS is positioned in the opposite orientation in SoxS-TACIII to that in SoxS-TACI and SoxS-TACII, unveiling a novel mode of transcription activation. Strikingly, two universally conserved C-terminal domains of alpha subunit (αCTD) of RNAP associate with each other, bridging SoxS and region 4 of σ70. We show that SoxS interacts with RNAP directly and independently from DNA, remodeling the enzyme to activate transcription from cognate SoxS promoters while repressing transcription from UP-element containing promoters. Our data provide a comprehensive summary of SoxS-dependent promoter architectures and offer new insights into the αCTD contribution to transcription control in bacteria.


Asunto(s)
Proteínas de Escherichia coli , Activación Transcripcional , Proteínas de Escherichia coli/metabolismo , Regulación Bacteriana de la Expresión Génica , Transactivadores/metabolismo , Sitios de Unión , ARN Polimerasas Dirigidas por ADN/metabolismo , Escherichia coli/genética , Escherichia coli/metabolismo , ADN/genética , ADN/metabolismo , Transcripción Genética , Proteínas Bacterianas/metabolismo
8.
Nucleic Acids Res ; 50(14): 8321-8330, 2022 08 12.
Artículo en Inglés | MEDLINE | ID: mdl-35871295

RESUMEN

AlpA positively regulates a programmed cell death pathway linked to the virulence of Pseudomonas aeruginosa by recognizing an AlpA binding element within the promoter, then binding RNA polymerase directly and allowing it to bypass an intrinsic terminator positioned downstream. Here, we report the single-particle cryo-electron microscopy structures of both an AlpA-loading complex and an AlpA-loaded complex. These structures indicate that the C-terminal helix-turn-helix motif of AlpA binds to the AlpA binding element and that the N-terminal segment of AlpA forms a narrow ring inside the RNA exit channel. AlpA was also revealed to render RNAP resistant to termination signals by prohibiting RNA hairpin formation in the RNA exit channel. Structural analysis predicted that AlpA, 21Q, λQ and 82Q share the same mechanism of transcription antitermination.


Asunto(s)
Proteínas Bacterianas , ARN Polimerasas Dirigidas por ADN , Proteínas de Unión al ARN , Transcripción Genética , Proteínas Bacterianas/metabolismo , Microscopía por Crioelectrón , ARN Polimerasas Dirigidas por ADN/metabolismo , Regiones Promotoras Genéticas , Conformación Proteica , Pseudomonas aeruginosa/genética , Pseudomonas aeruginosa/metabolismo , ARN , Proteínas de Unión al ARN/metabolismo
9.
Nat Commun ; 13(1): 4204, 2022 07 20.
Artículo en Inglés | MEDLINE | ID: mdl-35859063

RESUMEN

Pseudomonas aeruginosa (Pae) SutA adapts bacteria to hypoxia and nutrition-limited environment during chronic infection by increasing transcription activity of an RNA polymerase (RNAP) holoenzyme comprising the stress-responsive σ factor σS (RNAP-σS). SutA shows no homology to previously characterized RNAP-binding proteins. The structure and mode of action of SutA remain unclear. Here we determined cryo-EM structures of Pae RNAP-σS holoenzyme, Pae RNAP-σS holoenzyme complexed with SutA, and Pae RNAP-σS transcription initiation complex comprising SutA. The structures show SutA pinches RNAP-ß protrusion and facilitates promoter unwinding by wedging RNAP-ß lobe open. Our results demonstrate that SutA clears an energetic barrier to facilitate promoter unwinding of RNAP-σS holoenzyme.


Asunto(s)
ARN Polimerasas Dirigidas por ADN , Pseudomonas aeruginosa , Proteínas Bacterianas/metabolismo , ADN/metabolismo , ARN Polimerasas Dirigidas por ADN/metabolismo , Holoenzimas/metabolismo , Pseudomonas aeruginosa/metabolismo , Factor sigma/metabolismo , Transcripción Genética
10.
Nucleic Acids Res ; 50(10): 5974-5987, 2022 06 10.
Artículo en Inglés | MEDLINE | ID: mdl-35641097

RESUMEN

Rob, which serves as a paradigm of the large AraC/XylS family transcription activators, regulates diverse subsets of genes involved in multidrug resistance and stress response. However, the underlying mechanism of how it engages bacterial RNA polymerase and promoter DNA to finely respond to environmental stimuli is still elusive. Here, we present two cryo-EM structures of Rob-dependent transcription activation complex (Rob-TAC) comprising of Escherichia coli RNA polymerase (RNAP), Rob-regulated promoter and Rob in alternative conformations. The structures show that a single Rob engages RNAP by interacting with RNAP αCTD and σ70R4, revealing their generally important regulatory roles. Notably, by occluding σ70R4 from binding to -35 element, Rob specifically binds to the conserved Rob binding box through its consensus HTH motifs, and retains DNA bending by aid of the accessory acidic loop. More strikingly, our ligand docking and biochemical analysis demonstrate that the large Rob C-terminal domain (Rob CTD) shares great structural similarity with the global Gyrl-like domains in effector binding and allosteric regulation, and coordinately promotes formation of competent Rob-TAC. Altogether, our structural and biochemical data highlight the detailed molecular mechanism of Rob-dependent transcription activation, and provide favorable evidences for understanding the physiological roles of the other AraC/XylS-family transcription factors.


Asunto(s)
Proteínas de Unión al ADN , Proteínas de Escherichia coli , Factor de Transcripción de AraC/genética , Factor de Transcripción de AraC/metabolismo , Proteínas Bacterianas/metabolismo , Citarabina/metabolismo , ADN/química , Proteínas de Unión al ADN/metabolismo , ARN Polimerasas Dirigidas por ADN/genética , ARN Polimerasas Dirigidas por ADN/metabolismo , Escherichia coli/genética , Escherichia coli/metabolismo , Proteínas de Escherichia coli/metabolismo , Regulación Bacteriana de la Expresión Génica , Activación Transcripcional
11.
Nat Plants ; 7(10): 1389-1396, 2021 10.
Artículo en Inglés | MEDLINE | ID: mdl-34593993

RESUMEN

MicroRNAs (miRNAs) are short non-coding RNAs that inhibit the expression of target genes by directly binding to their mRNAs. In animals, pri-miRNAs are cleaved by Drosha to generate pre-miRNAs, which are subsequently cleaved by Dicer to generate mature miRNAs. Instead of being cleaved by two different enzymes, both cleavages in plants are performed by Dicer-like 1 (DCL1). With a similar domain architecture as human Dicer, it is mysterious how DCL1 recognizes pri-miRNAs and performs two cleavages sequentially. Here, we report the single-particle cryo-electron microscopy structures of Arabidopsis DCL1 complexed with a pri-miRNA and a pre-miRNA, respectively, in cleavage-competent states. These structures uncover the plasticity of the PAZ domain, which is critical for the recognition of both pri-miRNA and pre-miRNA. These structures suggest that the helicase module serves as an engine that transfers the substrate between two sequential cleavage events. This study lays a foundation for dissecting the regulation mechanism of miRNA biogenesis in plants and provides insights into the dicing state of human Dicer.


Asunto(s)
Proteínas de Arabidopsis/genética , Arabidopsis/metabolismo , Proteínas de Ciclo Celular/genética , MicroARNs/metabolismo , Procesamiento Postranscripcional del ARN , ARN de Planta/metabolismo , Ribonucleasa III/genética , Proteínas de Arabidopsis/metabolismo , Proteínas de Ciclo Celular/metabolismo , Microscopía por Crioelectrón , Ribonucleasa III/metabolismo
12.
Nucleic Acids Res ; 49(18): 10756-10769, 2021 10 11.
Artículo en Inglés | MEDLINE | ID: mdl-34530448

RESUMEN

Spx is a global transcriptional regulator in Gram-positive bacteria and has been inferred to efficiently activate transcription upon oxidative stress by engaging RNA polymerase (RNAP) and promoter DNA. However, the precise mechanism by which it interacts with RNAP and promoter DNA to initiate transcription remains obscure. Here, we report the cryo-EM structure of an intact Spx-dependent transcription activation complex (Spx-TAC) from Bacillus subtilis at 4.2 Å resolution. The structure traps Spx in an active conformation and defines key interactions accounting for Spx-dependent transcription activation. Strikingly, an oxidized Spx monomer engages RNAP by simultaneously interacting with the C-terminal domain of RNAP alpha subunit (αCTD) and σA. The interface between Spx and αCTD is distinct from those previously reported activators, indicating αCTD as a multiple target for the interaction between RNAP and various transcription activators. Notably, Spx specifically wraps the conserved -44 element of promoter DNA, thereby stabilizing Spx-TAC. Besides, Spx interacts extensively with σA through three different interfaces and promotes Spx-dependent transcription activation. Together, our structural and biochemical results provide a novel mechanistic framework for the regulation of bacterial transcription activation and shed new light on the physiological roles of the global Spx-family transcription factors.


Asunto(s)
Proteínas Bacterianas/química , Transactivadores/química , Activación Transcripcional , Bacillus subtilis , Microscopía por Crioelectrón , ARN Polimerasas Dirigidas por ADN/química , Modelos Moleculares , Estrés Oxidativo , Regiones Promotoras Genéticas , Factor sigma/química
13.
Nat Commun ; 12(1): 1131, 2021 02 18.
Artículo en Inglés | MEDLINE | ID: mdl-33602900

RESUMEN

Transcription activation of bacteriophage T4 late genes is accomplished by a transcription activation complex containing RNA polymerase (RNAP), the promoter specificity factor gp55, the coactivator gp33, and a universal component of cellular DNA replication, the sliding clamp gp45. Although genetic and biochemical studies have elucidated many aspects of T4 late gene transcription, no precise structure of the transcription machinery in the process is available. Here, we report the cryo-EM structures of a gp55-dependent RNAP-promoter open complex and an intact gp45-dependent transcription activation complex. The structures reveal the interactions between gp55 and the promoter DNA that mediate the recognition of T4 late promoters. In addition to the σR2 homology domain, gp55 has a helix-loop-helix motif that chaperons the template-strand single-stranded DNA of the transcription bubble. Gp33 contacts both RNAP and the upstream double-stranded DNA. Gp45 encircles the DNA and tethers RNAP to it, supporting the idea that gp45 switches the promoter search from three-dimensional diffusion mode to one-dimensional scanning mode.


Asunto(s)
ADN Polimerasa III/metabolismo , Escherichia coli/enzimología , Escherichia coli/genética , Activación Transcripcional/genética , Secuencias de Aminoácidos , Secuencia de Bases , ADN Polimerasa III/química , ADN Polimerasa III/ultraestructura , ADN de Cadena Simple/metabolismo , ADN Viral/metabolismo , ARN Polimerasas Dirigidas por ADN/metabolismo , Modelos Genéticos , Modelos Moleculares , Regiones Promotoras Genéticas , Unión Proteica , Dominios Proteicos , Factor sigma/química , Factor sigma/ultraestructura , Transcripción Genética , Proteínas Virales/química , Proteínas Virales/ultraestructura
14.
Nucleic Acids Res ; 48(20): 11762-11772, 2020 11 18.
Artículo en Inglés | MEDLINE | ID: mdl-33068413

RESUMEN

Mfd-dependent transcription termination plays an important role in transcription-coupled DNA repair, transcription-replication conflict resolution, and antimicrobial resistance development. Despite extensive studies, the molecular mechanism of Mfd-dependent transcription termination in bacteria remains unclear, with several long-standing puzzles. How Mfd is activated by stalled RNA polymerase (RNAP) and how activated Mfd translocates along the DNA are unknown. Here, we report the single-particle cryo-electron microscopy structures of T. thermophilus Mfd-RNAP complex with and without ATPγS. The structures reveal that Mfd undergoes profound conformational changes upon activation, contacts the RNAP ß1 domain and its clamp, and pries open the RNAP clamp. These structures provide a foundation for future studies aimed at dissecting the precise mechanism of Mfd-dependent transcription termination and pave the way for rational drug design targeting Mfd for the purpose of tackling the antimicrobial resistance crisis.


Asunto(s)
Proteínas Bacterianas/química , Factores de Transcripción/química , Terminación de la Transcripción Genética , Adenosina Trifosfato/análogos & derivados , Adenosina Trifosfato/química , Microscopía por Crioelectrón , ADN Bacteriano/química , ARN Polimerasas Dirigidas por ADN/química , Modelos Moleculares , Thermus thermophilus
15.
Nucleic Acids Res ; 48(17): 9931-9942, 2020 09 25.
Artículo en Inglés | MEDLINE | ID: mdl-32785630

RESUMEN

Stringent starvation protein A (SspA) is an RNA polymerase (RNAP)-associated protein involved in nucleotide metabolism, acid tolerance and virulence of bacteria. Despite extensive biochemical and genetic analyses, the precise regulatory role of SspA in transcription is still unknown, in part, because of a lack of structural information for bacterial RNAP in complex with SspA. Here, we report a 3.68 Å cryo-EM structure of an Escherichia coli RNAP-promoter open complex (RPo) with SspA. Unexpectedly, the structure reveals that SspA binds to the E. coli σ70-RNAP holoenzyme as a homodimer, interacting with σ70 region 4 and the zinc binding domain of EcoRNAP ß' subunit simultaneously. Results from fluorescent polarization assays indicate the specific interactions between SspA and σ70 region 4 confer its σ selectivity, thereby avoiding its interactions with σs or other alternative σ factors. In addition, results from in vitro transcription assays verify that SspA inhibits transcription probably through suppressing promoter escape. Together, the results here provide a foundation for understanding the unique physiological function of SspA in transcription regulation in bacteria.


Asunto(s)
ARN Polimerasas Dirigidas por ADN/genética , Proteínas de Escherichia coli/química , Regiones Promotoras Genéticas , Sitios de Unión , Microscopía por Crioelectrón , ARN Polimerasas Dirigidas por ADN/metabolismo , Escherichia coli/genética , Escherichia coli/metabolismo , Proteínas de Escherichia coli/metabolismo , Simulación del Acoplamiento Molecular , Unión Proteica
16.
Nucleic Acids Res ; 47(17): 9423-9432, 2019 09 26.
Artículo en Inglés | MEDLINE | ID: mdl-31392983

RESUMEN

Bacteriophage T4 middle promoters are activated through a process called σ appropriation, which requires the concerted effort of two T4-encoded transcription factors: AsiA and MotA. Despite extensive biochemical and genetic analyses, puzzle remains, in part, because of a lack of precise structural information for σ appropriation complex. Here, we report a single-particle cryo-electron microscopy (cryo-EM) structure of an intact σ appropriation complex, comprising AsiA, MotA, Escherichia coli RNA polymerase (RNAP), σ70 and a T4 middle promoter. As expected, AsiA binds to and remodels σ region 4 to prevent its contact with host promoters. Unexpectedly, AsiA undergoes a large conformational change, takes over the job of σ region 4 and provides an anchor point for the upstream double-stranded DNA. Because σ region 4 is conserved among bacteria, other transcription factors may use the same strategy to alter the landscape of transcription immediately. Together, the structure provides a foundation for understanding σ appropriation and transcription activation.


Asunto(s)
Proteínas de Unión al ADN/ultraestructura , ARN Polimerasas Dirigidas por ADN/ultraestructura , Factores de Transcripción/ultraestructura , Proteínas Virales/ultraestructura , Bacteriófago T4/química , Bacteriófago T4/genética , Bacteriófago T4/ultraestructura , ADN , Proteínas de Unión al ADN/química , Proteínas de Unión al ADN/genética , ARN Polimerasas Dirigidas por ADN/química , ARN Polimerasas Dirigidas por ADN/genética , Escherichia coli/genética , Complejos Multiproteicos/genética , Complejos Multiproteicos/ultraestructura , Regiones Promotoras Genéticas/genética , Conformación Proteica , Factores de Transcripción/química , Factores de Transcripción/genética , Proteínas Virales/genética
17.
Nat Commun ; 10(1): 2925, 2019 07 02.
Artículo en Inglés | MEDLINE | ID: mdl-31266960

RESUMEN

Bacteriophage Q protein engages σ-dependent paused RNA polymerase (RNAP) by binding to a DNA site embedded in late gene promoter and renders RNAP resistant to termination signals. Here, we report a single-particle cryo-electron microscopy (cryo-EM) structure of an intact Q-engaged arrested complex. The structure reveals key interactions responsible for σ-dependent pause, Q engagement, and Q-mediated transcription antitermination. The structure shows that two Q protomers (QI and QII) bind to a direct-repeat DNA site and contact distinct elements of the RNA exit channel. Notably, QI forms a narrow ring inside the RNA exit channel and renders RNAP resistant to termination signals by prohibiting RNA hairpin formation in the RNA exit channel. Because the RNA exit channel is conserved among all multisubunit RNAPs, it is likely to serve as an important contact site for regulators that modify the elongation properties of RNAP in other organisms, as well.


Asunto(s)
Bacteriófagos/enzimología , Codón de Terminación/genética , ARN Polimerasas Dirigidas por ADN/química , ARN Polimerasas Dirigidas por ADN/metabolismo , Transcripción Genética , Proteínas Virales/química , Proteínas Virales/metabolismo , Bacteriófagos/química , Bacteriófagos/genética , Codón de Terminación/metabolismo , Microscopía por Crioelectrón , ARN Polimerasas Dirigidas por ADN/genética , Escherichia coli/genética , Escherichia coli/metabolismo , Escherichia coli/virología , Regiones Promotoras Genéticas , Proteínas Virales/genética
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