Sergei Borukhov scite author profile

In bacteria, the binding of a single protein, the initiation factor sigma, to a multi-subunit RNA polymerase core enzyme results in the formation of a holoenzyme, the active form of RNA polymerase essential for transcription initiation. Here we report the crystal structure of a bacterial RNA polymerase holoenzyme from Thermus thermophilus at 2.6 A resolution. In the structure, two amino-terminal domains of the sigma subunit form a V-shaped structure near the opening of the upstream DNA-binding channel of the active site cleft. The carboxy-terminal domain of sigma is near the outlet of the RNA-exit channel, about 57 A from the N-terminal domains. The extended linker domain forms a hairpin protruding into the active site cleft, then stretching through the RNA-exit channel to connect the N- and C-terminal domains. The holoenzyme structure provides insight into the structural organization of transcription intermediate complexes and into the mechanism of transcription initiation.

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Eukaryotic ribosomes require initiation factors 1 and 1A to locate initiation codons

Pestova

Borukhov

Hellen

1998

Nature

377

410

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The scanning model of translation initiation is a coherent description of how eukaryotic ribosomes reach the initiation codon after being recruited to the capped 5' end of messenger RNA. Five eukaryotic initiation factors (eIF 2, 3, 4A, 4B and 4F) with established functions have been assumed to be sufficient to mediate this process. Here we report that eIF1 and eIF1A are also both essential for translation initiation. In their absence, 43S ribosomal preinitiation complexes incubated with ATP, eIF4A, eIF4B and eIF4F bind exclusively to the cap-proximal region but are unable to reach the initiation codon. Individually, eIF1A enhances formation of this cap-proximal complex, and eIF1 weakly promotes formation of a 48S ribosomal complex at the initiation codon. These proteins act synergistically to mediate assembly of ribosomal initiation complexes at the initiation codon and dissociate aberrant complexes from the mRNA.

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Transcript cleavage factors from E. coli

Borukhov¹,

Sagitov²,

Goldfarb³

1993

Cell

351

359

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Crystal structure of a bacterial RNA polymerase holoenzyme at 2.6 Å resolution

Vassylyev¹,

Sekine²,

Laptenko³

et al. 2002

Acta Cryst Sect A

128

304

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Release of initiation factors from 48S complexes during ribosomal subunit joining and the link between establishment of codon-anticodon base-pairing and hydrolysis of eIF2-bound GTP

Unbehaun¹,

Borukhov²,

Hellen³

et al. 2004

Genes Dev.

203

277

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The 40S subunit in 48S complexes formed at the initiation codon of mRNA is bound to eukaryotic initiation factor (eIF) 3, eIF1, eIF1A, and an eIF2/GTP/Met-tRNA Met i ternary complex and can therefore not join a 60S subunit directly to form an 80S ribosome. We report that eIF5-induced hydrolysis of eIF2-bound GTP in 48S complexes led to release of eIF2-GDP but not eIF3 or eIF1. eIF5B did not influence factor release in the absence of 60S subunits. Therefore eIF3 and eIF1 dissociate from 40S subunits during, rather than before, the eIF5B-mediated subunit joining event. In the absence of eIF1, eIF5-stimulated hydrolysis of eIF2-bound GTP occurred at the same rate in 43S pre-initiation and 48S initiation complexes. GTP hydrolysis in 43S complexes assembled with eIF1 was much slower than in 43S or 48S complexes assembled without eIF1. Establishment of codon-anticodon base-pairing in 48S complexes relieved eIF1's inhibition. Thus, in addition to its role in initiation codon selection during 48S complex formation, eIF1 also participates in maintaining the fidelity of the initiation process at a later stage, hydrolysis of eIF2-bound GTP, by inhibiting premature GTP hydrolysis and by linking establishment of codon-anticodon base-pairing with GTP hydrolysis.[Keywords: Eukaryotic initiation factor 2; eukaryotic initiation factor 3; eukaryotic initiation factor 5; eukaryotic initiation factor 5B; GTP hydrolysis; translation] Supplemental material is available at http://www.genesdev.org.

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Transcript cleavage factors GreA and GreB act as transient catalytic components of RNA polymerase

et al. 2003

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O.Laptenko and J.Lee contributed equally to this workProkaryotic transcription elongation factors GreA and GreB stimulate intrinsic nucleolytic activity of RNA polymerase (RNAP). The proposed biological role of Gre-induced RNA hydrolysis includes transcription proofreading, suppression of transcriptional pausing and arrest, and facilitation of RNAP transition from transcription initiation to transcription elongation. Using an array of biochemical and molecular genetic methods, we mapped the interaction interface between Gre and RNAP and identi®ed the key residues in Gre responsible for induction of nucleolytic activity in RNAP. We propose a structural model in which the C-terminal globular domain of Gre binds near the opening of the RNAP secondary channel, the N-terminal coiled-coil domain (NTD) protrudes inside the RNAP channel, and the tip of the NTD is brought to the immediate vicinity of RNAP catalytic center. Two conserved acidic residues D41 and E44 located at the tip of the NTD assist RNAP by coordinating the Mg 2+ ion and water molecule required for catalysis of RNA hydrolysis. If so, Gre would be the ®rst transcription factor known to directly participate in the catalytic act of RNAP.

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Intrinsic transcript cleavage activity of RNA polymerase.

Orlova¹,

Newlands

Das

et al. 1995

Proc. Natl. Acad. Sci. U.S.A.

194

189

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Inhibition of Bacterial RNA Polymerase by Streptolydigin: Stabilization of a Straight-Bridge-Helix Active-Center Conformation

Tuske

Sarafianos

Wang

et al. 2005

Cell

183

188

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We define the target, mechanism, and structural basis of inhibition of bacterial RNA polymerase (RNAP) by the tetramic acid antibiotic streptolydigin (Stl). Stl binds to a site adjacent to but not overlapping the RNAP active center and stabilizes an RNAP-active-center conformational state with a straight-bridge helix. The results provide direct support for the proposals that alternative straight-bridge-helix and bent-bridge-helix RNAP-active-center conformations exist and that cycling between straight-bridge-helix and bent-bridge-helix RNAP-active-center conformations is required for RNAP function. The results set bounds on models for RNAP function and suggest strategies for design of novel antibacterial agents.

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Sergei Borukhov

Crystal structure of a bacterial RNA polymerase holoenzyme at 2.6 Å resolution

Eukaryotic ribosomes require initiation factors 1 and 1A to locate initiation codons

Transcript cleavage factors from E. coli

Crystal structure of a bacterial RNA polymerase holoenzyme at 2.6 Å resolution

Release of initiation factors from 48S complexes during ribosomal subunit joining and the link between establishment of codon-anticodon base-pairing and hydrolysis of eIF2-bound GTP

Transcript cleavage factors GreA and GreB act as transient catalytic components of RNA polymerase

Intrinsic transcript cleavage activity of RNA polymerase.

Inhibition of Bacterial RNA Polymerase by Streptolydigin: Stabilization of a Straight-Bridge-Helix Active-Center Conformation

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