Biochemical Analysis of Yeast Suppressor of Ty 4/5 (Spt4/5) Reveals the Importance of Nucleic Acid Interactions in the Prevention of RNA Polymerase II Arrest

Crickard, J. Brooks; Fu, Jiyang; Reese, Joseph C.

doi:10.1074/jbc.m116.716001

Cited by 50 publications

(88 citation statements)

References 77 publications

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“…The stimulation of RNA chain elongation by NusG has been documented in vitro for bacterial (Burova et al, 1995), archaeal (Hirtreiter et al, 2010) and eukaryotic (Wada et al, 1998) transcription systems. The NTD is sufficient for these effects on elongation, but the structural elements that superimpose well between the bacterial NusG NTD and the archaeal Spt5 NTD (Figure 8C) are limited to ( i ) the beta sheet that comprises the RNAP-binding site, ( ii ) the conserved five amino acid loop that we implicate in the anti-backtracking action of E. coli NusG, and ( iii ) the N-terminus of the α-helix that follows this loop and possibly interacts with the single-stranded non-template DNA (Crickard et al, 2016). The lack of the strong conservation of the surface residues (Figure 8D) suggests that the anti-backtracking activity may be determined by the overall fold of the NusG NTD and is only weakly dependent on the nature of the individual amino acid side-chains, consistent with the mutational analysis of E. coli NusG (Mooney et al, 2009b).…”

Section: Discussionmentioning

confidence: 99%

NusG inhibits RNA polymerase backtracking by stabilizing the minimal transcription bubble

Turtola

Belogurov

2016

eLife

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Universally conserved factors from NusG family bind at the upstream fork junction of transcription elongation complexes and modulate RNA synthesis in response to translation, processing, and folding of the nascent RNA. Escherichia coli NusG enhances transcription elongation in vitro by a poorly understood mechanism. Here we report that E. coli NusG slows Gre factor-stimulated cleavage of the nascent RNA, but does not measurably change the rates of single nucleotide addition and translocation by a non-paused RNA polymerase. We demonstrate that NusG slows RNA cleavage by inhibiting backtracking. This activity is abolished by mismatches in the upstream DNA and is independent of the gate and rudder loops, but is partially dependent on the lid loop. Our comprehensive mapping of the upstream fork junction by base analogue fluorescence and nucleic acids crosslinking suggests that NusG inhibits backtracking by stabilizing the minimal transcription bubble.DOI: http://dx.doi.org/10.7554/eLife.18096.001

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Section: Discussionmentioning

confidence: 99%

NusG inhibits RNA polymerase backtracking by stabilizing the minimal transcription bubble

Turtola

Belogurov

2016

eLife

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“…4C). Crickard et al recently reported that replacing six residues of Spt5, a yeast homolog of NusG, located on the same face as the SWHL NusG motif with alanines abolished Spt5 cross-linking to the NT DNA and its anti-arrest activity (31). Although it is uncertain if the altered surface residues (which are only weakly conserved) or more extensive structural changes (such as local refolding caused by altered core residues) lead to the observed phenotypes, it seems probable that the four-alanine substitution in NusG abolishes its anti-pausing activity by altering interactions with the NT DNA and not with the GL.…”

Section: Resultsmentioning

confidence: 99%

RNA polymerase gate loop guides the nontemplate DNA strand in transcription complexes

NandyMazumdar

Nedialkov

Svetlov

et al. 2016

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

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Upon RNA polymerase (RNAP) binding to a promoter, the σ factor initiates DNA strand separation and captures the melted nontemplate DNA, whereas the core enzyme establishes interactions with the duplex DNA in front of the active site that stabilize initiation complexes and persist throughout elongation. Among many core RNAP elements that participate in these interactions, the β′ clamp domain plays the most prominent role. In this work, we investigate the role of the β gate loop, a conserved and essential structural element that lies across the DNA channel from the clamp, in transcription regulation. The gate loop was proposed to control DNA loading during initiation and to interact with NusG-like proteins to lock RNAP in a closed, processive state during elongation. We show that the removal of the gate loop has large effects on promoter complexes, trapping an unstable intermediate in which the RNAP contacts with the nontemplate strand discriminator region and the downstream duplex DNA are not yet fully established. We find that although RNAP lacking the gate loop displays moderate defects in pausing, transcript cleavage, and termination, it is fully responsive to the transcription elongation factor NusG. Together with the structural data, our results support a model in which the gate loop, acting in concert with initiation or elongation factors, guides the nontemplate DNA in transcription complexes, thereby modulating their regulatory properties.D uring each round of transcription, RNA polymerase (RNAP) establishes, maintains, and finally releases contacts with the DNA template and the RNA. These interactions mediate highly selective initiation, processive elongation, and precise termination and can be tuned to enable intricate regulation during the transcription cycle. RNAP resembles a crab claw in which the two pincers composed of the β′ and β subunits form an active site cleft that accommodates the nucleic acid chains (Fig. 1). The mobile β′ clamp domain that forms one of the pincers stands out as a central regulatory feature (1,2). The open clamp likely allows the loading of the promoter DNA during initiation and the release of the template and the nascent RNA during termination. The clamp is thought to close to form an active initiation complex and to remain closed during elongation but may open partially at a hairpindependent pause site (3).The clamp movements may be linked to those of the β lobe domain, which forms a part of the second pincer. The β gate loop (GL), which lies across the RNAP cleft from the tip of the clamp (Fig. 1), has been identified as an element that restricts the entry of the duplex promoter DNA into the narrow active site cleft (4), allowing only a single strand of DNA to pass through. This model posited that the DNA stands must separate outside the cleft before entry into RNAP, whereas footprinting studies demonstrated that the promoter DNA enters the active site cleft before it is opened (5). This controversy was a subject of an intense debate until a recent study revealed that the...

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“…In support of this idea, the elongation factor Spt4/5 targets the same position on the Pol II cleft as p53, displaying a closed conformation within the context of an elongation complex (Gnatt et al 2001;Kostek et al 2006;Bernecky et al 2016). Importantly, Spt4/5 directly interacts with the clamp domain to both positively and negatively regulate Pol II elongation (Yamaguchi et al 1999;Bernecky et al 2016;Crickard et al 2016).…”

Section: Discussionmentioning

confidence: 99%

“…This indicates that p53 could retain its ability to associate with DNA directly while in complex with Pol II. Perhaps this ability could allow p53 to mimic elongation factors Spt4/5 and NusG, which stabilize the upstream DNA and the nontemplate strand in the transcription bubble to help prevent Pol II backtracking (Herbert et al 2010;Chakraborty et al 2012;Bernecky et al 2016;Crickard et al 2016). Therefore, a conserved structural mechanism may be used by p53, Spt4/5, and NusG to modulate Pol II elongation activity.…”

Section: Discussionmentioning

confidence: 99%

Structural visualization of the p53/RNA polymerase II assembly

et al. 2016

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The master tumor suppressor p53 activates transcription in response to various cellular stresses in part by facilitating recruitment of the transcription machinery to DNA. Recent studies have documented a direct yet poorly characterized interaction between p53 and RNA polymerase II (Pol II). Therefore, we dissected the human p53/Pol II interaction via single-particle cryo-electron microscopy, structural docking, and biochemical analyses. This study reveals that p53 binds Pol II via the Rpb1 and Rpb2 subunits, bridging the DNA-binding cleft of Pol II proximal to the upstream DNA entry site. In addition, the key DNA-binding surface of p53, frequently disrupted in various cancers, remains exposed within the assembly. Furthermore, the p53/Pol II cocomplex displays a closed conformation as defined by the position of the Pol II clamp domain. Notably, the interaction of p53 and Pol II leads to increased Pol II elongation activity. These findings indicate that p53 may structurally regulate DNA-binding functions of Pol II via the clamp domain, thereby providing insights into p53-regulated Pol II transcription.

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Biochemical Analysis of Yeast Suppressor of Ty 4/5 (Spt4/5) Reveals the Importance of Nucleic Acid Interactions in the Prevention of RNA Polymerase II Arrest

Cited by 50 publications

References 77 publications

NusG inhibits RNA polymerase backtracking by stabilizing the minimal transcription bubble

NusG inhibits RNA polymerase backtracking by stabilizing the minimal transcription bubble

RNA polymerase gate loop guides the nontemplate DNA strand in transcription complexes

Structural visualization of the p53/RNA polymerase II assembly

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