Pausing controls branching between productive and non-productive pathways during initial transcription in bacteria

Dulin, David; Bauer, David L.V.; Malinen, Anssi M.; Bakermans, Jacob J. W.; Kaller, M; Morichaud, Zakia; Petushkov, Ivan; Depken, Martin; Brodolin, Konstantin; Kulbachinskiy, Andrey; Kapanidis, Achillefs N.

doi:10.1038/s41467-018-03902-9

Cited by 66 publications

(101 citation statements)

References 67 publications

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“…We infer that initial-transcription pausing and transcription-elongation pausing share mechanistic commonalities. Consistent with this proposal, substitution of the RNAP b-subunit residue 446 (b D446A ), increases sequence-dependent pausing in both initial transcription ( Figure 3A; Dulin et al, 2018) and transcription elongation (Vvedenskaya et al, 2014). (Figures 4, S2), (iii) showed that initial-transcription pausing can occur at each promoter position in the promoter-initial-transcribed region from +3 to +9 (Figures 4, S2), (iv) and showed that the s finger contributes quantitatively to pausing at promoter positions +5 and +6, presumably through collision with the RNA 5ʹ end (Figures 3, 5E,F).…”

Section: Relationship Between Sequence Determinants For Initial-transsupporting

confidence: 71%

“…Plots of RNAP occupancy as a function of initial-transcribed-region sequence shows graphically that RNAP occupancy strongly correlates with match to the consensus sequence for each position ( Figure S4). We note that placCONS, the promoter previously shown to exhibit initial-transcription pausing at a position in the range +5 to +7 in vitro (Duchi et al, 2016;Lerner et al, 2016;Dulin et al, 2018), and shown here to exhibit initial transcription pausing at position +6 in vitro and in vivo (Figure 3), contains a 3-of-3 match to the consensus sequence in the register that would yield initial transcription pausing at position +6 (compare Figure 3A and Figure 5A).…”

Section: Promoter-sequence Determinants For Initial-transcription Pausupporting

confidence: 52%

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XACT-seq comprehensively defines the promoter-position and promoter-sequence determinants for initial-transcription pausing

Winkelman

Pukhrambam

Vvedenskaya

et al. 2019

Preprint

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Pausing by RNA polymerase (RNAP) during transcription elongation, in which a translocating RNAP uses a "stepping" mechanism, has been studied extensively, but pausing by RNAP during initial transcription, in which a promoter-anchored RNAP uses a "scrunching" mechanism, has not. We report a method that directly defines RNAP-active-center position relative to DNA in vivo with single-nucleotide resolution (XACT-seq;crosslink-between-active-center-and-template sequencing). We apply this method to detect and quantify pausing in initial transcription at 4 11 (~4,000,000) promoter sequences in vivo, in Escherichia coli. The results show initial-transcription pausing can occur in each nucleotide addition during initial transcription, particularly the first 4-5 nucleotide additions. The results further show initial-transcription pausing occurs at sequences that resemble the consensus sequence element for transcription-elongation pausing. Our findings define the positional and sequence determinants for initial-transcription pausing and establish initial-transcription pausing is hard-coded by sequence elements similar to those for transcription-elongation pausing.

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Section: Relationship Between Sequence Determinants For Initial-transsupporting

confidence: 71%

Section: Promoter-sequence Determinants For Initial-transcription Pausupporting

confidence: 52%

XACT-seq comprehensively defines the promoter-position and promoter-sequence determinants for initial-transcription pausing

Winkelman

Pukhrambam

Vvedenskaya

et al. 2019

Preprint

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“…The high FRET state presumably represents the scrunched DNA template at position +2, and our results suggest that the scrunched TIC can become unscrunched, switching to a conformation similar to that of the open promoter state, and can sometimes even switch back to the closed promoter state, presumably following the dissociation of RNA product by abortive initiation. Such scrunching-unscrunching dynamics during transcription initiation were recently observed in bacterial transcription machinery and were suggested to provide a paused checkpoint for abortive and productive RNA synthesis 3 . Upon stalling the TIC at positions +3, +5, +6, and +7, the major FRET population progressively rose to higher FRET levels of 0.63, 0.66, 0.76, and 0.79, respectively.…”

Section: Resultsmentioning

confidence: 67%

“…Recent studies of transcription machinery have found that transcription initiation is not a unidirectional process that invariably leads to elongation, but is rather a stochastic process that involves divergent pathways such as abortive initiation, backtracking, and pausing in addition to the progression to elongation 1-6 . These findings suggest that clearing initiation and progressing to elongation might be rate-determining steps that control transcription efficiency, and they have been suggested to be targets of transcription regulation 3,7-9 . Transcription systems across lineages with different levels of complexity show highly variable initiation efficiencies that depend on specific DNA elements 10,11 .…”

Section: Introductionmentioning

confidence: 86%

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The Dynamic Landscape of Transcription Initiation in Yeast Mitochondria

Sohn

Basu

Lee

et al. 2019

Preprint

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12Controlling efficiency and fidelity in the early stage of mitochondrial DNA transcription is 13 crucial for regulating cellular energy metabolism. Studies of bacteriophage and bacterial 14 systems have revealed that transcription occurs through a series of conformational transitions 15 during the initiation and elongation stages; however, how the conformational dynamics 16 progress throughout these stages remains unknown. Here, we used single-molecule 17 fluorescence resonance energy transfer techniques to examine the conformational dynamics 18 of the two-component transcription system of yeast mitochondria with single-base resolution. 19We show that, unlike its single-component homologue in bacteriophages, the yeast 20 mitochondrial transcription initiation complex dynamically transitions between closed, open, 21 and scrunched conformations throughout the initiation stage, and then makes a sharp 22 irreversible transition to an unbent conformation by promoter release at position +8. 23Remarkably, stalling the initiation complex revealed unscrunching dynamics without 24 dissociating the RNA transcript, manifesting the existence of backtracking transitions with 1 possible regulatory roles. The dynamic landscape of transcription initiation revealed here 2 suggests a kinetically driven regulation of mitochondrial transcription. 3 4 stabilizing open promoter regions 6,[16][17][18] . Similarly, human mitochondrial transcription 1 requires the initiation factors TFAM and TFB2M [19][20][21] . Mtf1 is structurally and functionally 2 homologous to TFB2M 19,22 , and is functionally similar to the bacterial sigma factor 23-25 . To 3 regulate transcription efficiency at various promoters, these transcription systems have 4 developed a set of molecular mechanisms, in which they share several key features. Both 5 bacteriophage and bacterial RNAPs show scrunching of the downstream DNA into the active 6 site as the RNA-DNA hybrid and the transcription bubble grow during initiation. After a 7 stable full-length RNA-DNA hybrid is formed, the RNAP releases upstream promoter 8 contacts and the initiation bubble collapses to drive the transition into elongation 26-32 . A 9 similar mechanism is also thought to exist in higher organisms 33,34 . More recently, branching 10 between competing pathways and pausing during initiation have been observed in both 11 bacteriophages and bacteria and may play crucial roles in regulating transcription 12 activity 1,3,4,35 . 13 In yeast mitochondria, transcription initiates with the assembly of Rpo41 and Mtf1 at 14 conserved promoter sequences located at positions −8 to +1 relative to the transcription start 15 site. The 2-aminopurine (2AP) fluorescence and protein-DNA crosslinking experiments have 16shown that Mtf1 facilitates promoter melting at positions −4 to +2 by trapping the non-17 template strand 24,25,36 . The structures of T7 and human mitochondrial RNAPs show that the 18 promoter DNA is severely bent around the start-site in the open complex 37,38 . Single-19 molecule studies of ...

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Cotranscriptional RNA Chemical Probing

Szyjka

Strobel

2022

Methods in Molecular Biology

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Pausing controls branching between productive and non-productive pathways during initial transcription in bacteria

Cited by 66 publications

References 67 publications

XACT-seq comprehensively defines the promoter-position and promoter-sequence determinants for initial-transcription pausing

XACT-seq comprehensively defines the promoter-position and promoter-sequence determinants for initial-transcription pausing

The Dynamic Landscape of Transcription Initiation in Yeast Mitochondria

Cotranscriptional RNA Chemical Probing

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