The Function of an Alternate TFB from Pyrococus furiosus and the Orientation of the TFB B-reader within Archaeal Transcription Initiation Complexes

ABSTRACT The genome of the hyperthermophile archaeon Pyrococcus furiosus encodes two transcription factor B (TFB) paralogs, one of which (TFB1) was previously characterized in transcription initiation. The second TFB (TFB2) is unusual in that it lacks recognizable homology to the archaeal TFB/eukaryotic TFIIB B-finger motif. TFB2 functions poorly in promoter-dependent transcription initiation, but photochemical cross-linking experiments indicated that the orientation and occupancy of transcription complexes formed with TFB2 at the strong gdh promoter are similar to the orientation and occupancy of transcription complexes formed with TFB1. Initiation complexes formed by TFB2 display a promoter opening defect that can be bypassed with a preformed transcription bubble, suggesting a mechanism to explain the low TFB2 transcription activity. Domain swaps between TFB1 and TFB2 showed that the low activity of TFB2 is determined mainly by its N terminus. The low activity of TFB2 in promoter opening and transcription can be partially relieved by transcription factor E (TFE). The results indicate that the TFB N-terminal region, containing conserved Zn ribbon and B-finger motifs, is important in promoter opening and that TFE can compensate for defects in the N terminus through enhancement of promoter opening.

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Transcription by Methanothermobacter thermautotrophicus RNA Polymerase In Vitro Releases Archaeal Transcription Factor B but Not TATA-Box Binding Protein from the Template DNA

Journal of Bacteriology ◽

10.1128/jb.186.18.6306-6310.2004 ◽

2004 ◽

Vol 186 (18) ◽

pp. 6306-6310 ◽

Cited By ~ 8

Author(s):

Yunwei Xie ◽

John N. Reeve

Keyword(s):

Transcription Factor ◽

Rna Polymerase ◽

Transcription Initiation ◽

Tata Box ◽

Factor B ◽

Methanothermobacter Thermautotrophicus ◽

Archaeal Transcription ◽

Tata Box Binding Protein ◽

Template Dna

ABSTRACT Transcription initiation in Archaea requires the assembly of a preinitiation complex containing the TATA- box binding protein (TBP), transcription factor B (TFB), and RNA polymerase (RNAP). The results reported establish the fate of Methanothermobacter thermautotrophicus TBP and TFB following transcription initiation by M. thermautotrophicus RNAP in vitro. TFB is released after initiation, during extension of the transcript from 4 to 24 nucleotides, but TBP remains bound to the template DNA. Regulation of archaeal transcription initiation by a repressor competition with TBP for TATA-box region binding must accommodate this observation.

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Archaeal transcription factors and their role in transcription initiation

FEMS Microbiology Reviews ◽

10.1111/j.1574-6976.1996.tb00234.x ◽

1996 ◽

Vol 18 (2-3) ◽

pp. 159-171 ◽

Cited By ~ 89

Author(s):

Michael Thomm

Keyword(s):

Transcription Factors ◽

Transcription Initiation ◽

Archaeal Transcription

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Transcription initiation factor TBP: old friend new questions

Biochemical Society Transactions ◽

10.1042/bst20180623 ◽

2019 ◽

Vol 47 (1) ◽

pp. 411-423 ◽

Cited By ~ 13

Author(s):

Kevin Kramm ◽

Christoph Engel ◽

Dina Grohmann

Keyword(s):

Transcription Initiation ◽

Initiation Factor ◽

Regulation Of Transcription ◽

Eukaryotic Transcription ◽

Initiation Factors ◽

Transcription System ◽

Σ Factor ◽

Domains Of Life ◽

Archaeal Transcription ◽

Rnap Ii

Abstract In all domains of life, the regulation of transcription by DNA-dependent RNA polymerases (RNAPs) is achieved at the level of initiation to a large extent. Whereas bacterial promoters are recognized by a σ-factor bound to the RNAP, a complex set of transcription factors that recognize specific promoter elements is employed by archaeal and eukaryotic RNAPs. These initiation factors are of particular interest since the regulation of transcription critically relies on initiation rates and thus formation of pre-initiation complexes. The most conserved initiation factor is the TATA-binding protein (TBP), which is of crucial importance for all archaeal-eukaryotic transcription initiation complexes and the only factor required to achieve full rates of initiation in all three eukaryotic and the archaeal transcription systems. Recent structural, biochemical and genome-wide mapping data that focused on the archaeal and specialized RNAP I and III transcription system showed that the involvement and functional importance of TBP is divergent from the canonical role TBP plays in RNAP II transcription. Here, we review the role of TBP in the different transcription systems including a TBP-centric discussion of archaeal and eukaryotic initiation complexes. We furthermore highlight questions concerning the function of TBP that arise from these findings.

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Fluorescently labeled recombinant RNAP system to probe archaeal transcription initiation

Methods ◽

10.1016/j.ymeth.2015.04.017 ◽

2015 ◽

Vol 86 ◽

pp. 10-18 ◽

Cited By ~ 9

Author(s):

Sarah Schulz ◽

Kevin Kramm ◽

Finn Werner ◽

Dina Grohmann

Keyword(s):

Transcription Initiation ◽

Archaeal Transcription

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Transcription factor/DNA interactions visualized by electron spectroscopic imaging

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100122654 ◽

1992 ◽

Vol 50 (1) ◽

pp. 450-451

Author(s):

David P. Bazett-Jones ◽

Mark L. Brown

Keyword(s):

Transcription Factor ◽

Dna Sequences ◽

Transcription Initiation ◽

Molecular Mechanisms ◽

Phosphorus Content ◽

Spectroscopic Imaging ◽

Electron Spectroscopic Imaging ◽

Dna Backbone ◽

Two Parameters ◽

High Level

A multisubunit RNA polymerase enzyme is ultimately responsible for transcription initiation and elongation of RNA, but recognition of the proper start site by the enzyme is regulated by general, temporal and gene-specific trans-factors interacting at promoter and enhancer DNA sequences. To understand the molecular mechanisms which precisely regulate the transcription initiation event, it is crucial to elucidate the structure of the transcription factor/DNA complexes involved. Electron spectroscopic imaging (ESI) provides the opportunity to visualize individual DNA molecules. Enhancement of DNA contrast with ESI is accomplished by imaging with electrons that have interacted with inner shell electrons of phosphorus in the DNA backbone. Phosphorus detection at this intermediately high level of resolution (≈lnm) permits selective imaging of the DNA, to determine whether the protein factors compact, bend or wrap the DNA. Simultaneously, mass analysis and phosphorus content can be measured quantitatively, using adjacent DNA or tobacco mosaic virus (TMV) as mass and phosphorus standards. These two parameters provide stoichiometric information relating the ratios of protein:DNA content.

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High resolution mapping of nucleic acid containing complexes in vitro and in situ

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100162703 ◽

1996 ◽

Vol 54 ◽

pp. 48-49

Author(s):

D. P. Bazett-Jones ◽

M. J. Hendzel

Keyword(s):

Nucleic Acid ◽

High Resolution ◽

Transcription Initiation ◽

Molecular Mechanisms ◽

Heavy Atom ◽

Regulation Of Transcription ◽

High Exposure ◽

Resolution Mapping ◽

Tata Sequence

Structural analysis of combinations of nucleosomes and transcription factors on promoter and enhancer elements is necessary in order to understand the molecular mechanisms responsible for the regulation of transcription initiation. Such complexes are often not amenable to study by high resolution crystallographic techniques. We have been applying electron spectroscopic imaging (ESI) to specific problems in molecular biology related to transcription regulation. There are several advantages that this technique offers in studies of nucleoprotein complexes. First, an intermediate level of spatial resolution can be achieved because heavy atom contrast agents are not necessary. Second, mass and stoichiometric relationships of protein and nucleic acid can be estimated by phosphorus detection, an element in much higher proportions in nucleic acid than protein. Third, wrapping or bending of the DNA by the protein constituents can be observed by phosphorus mapping of the complexes. Even when ESI is used with high exposure of electrons to the specimen, important macromolecular information may be provided. For example, an image of the TATA binding protein (TBP) bound to DNA is shown in the Figure (top panel). It can be seen that the protein distorts the DNA away from itself and much of its mass sits off the DNA helix axis. Moreover, phosphorus and mass estimates demonstrate whether one or two TBP molecules interact with this particular promoter TATA sequence.

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