Regulatory effects of cotranscriptional <scp>RNA</scp> structure formation and transitions

Liu, Shengrui; Hu, Chun-Gen; Zhang, Jin‐Zhi

doi:10.1002/wrna.1350

Cited by 22 publications

(15 citation statements)

References 88 publications

(280 reference statements)

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“…The propensity for RNA folding directly depends on sequence-specific folding rates, transcription elongation rates and the rate of proteins binding to the RNA 97, 98 (FIG. 4b).…”

Section: Transcription and Splicing Interactionsmentioning

confidence: 99%

Splicing and transcription touch base: co-transcriptional spliceosome assembly and function

Herzel

Ottoz

Alpert

et al. 2017

Nat Rev Mol Cell Biol

310

284

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Several macromolecular machines collaborate to produce eukaryotic messenger RNA. RNA polymerase II (Pol II) translocates along genes that are up to millions of base pairs in length and generates a flexible RNA copy of the DNA template. This nascent RNA harbours introns that are removed by the spliceosome, which is a megadalton ribonucleoprotein complex that positions the distant ends of the intron into its catalytic centre. Emerging evidence that the catalytic spliceosome is physically close to Pol II in vivo implies that transcription and splicing occur on similar timescales and that the transcription and splicing machineries may be spatially constrained. In this Review, we discuss aspects of spliceosome assembly, transcription elongation and other co-transcriptional events that allow the temporal coordination of co-transcriptional splicing.

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“…The propensity for RNA folding directly depends on sequence-specific folding rates, transcription elongation rates and the rate of proteins binding to the RNA 97, 98 (FIG. 4b).…”

Section: Transcription and Splicing Interactionsmentioning

confidence: 99%

Splicing and transcription touch base: co-transcriptional spliceosome assembly and function

Herzel

Ottoz

Alpert

et al. 2017

Nat Rev Mol Cell Biol

310

284

View full text Add to dashboard Cite

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“…RNA folding begins as the transcript is being synthesized by RNA polymerase II (Pol II) 70–72 . Transcript elongation by Pol II is not continuous, but rather entails periods of active elongation interrupted by pauses and backtracking.…”

Section: Rna Structure: Higher-order Organizationmentioning

confidence: 99%

“…Transcript elongation by Pol II is not continuous, but rather entails periods of active elongation interrupted by pauses and backtracking. The formation of RNA structures, such as hairpins, on the nascent transcript can create physical barriers that prevent backtracking and promote forward elongation by Pol II 70, 71 . As splicing and polyadenylation are dependent upon Pol II elongation kinetics 73, 74 , RNA structure–elongation coupling likely affects downstream RNA processing.…”

Section: Rna Structure: Higher-order Organizationmentioning

confidence: 99%

RNA modifications and structures cooperate to guide RNA–protein interactions

Lewis

Pan

Kalsotra

2017

Nat Rev Mol Cell Biol

247

204

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An emerging body of evidence indicates that post-transcriptional gene regulation not only relies on the linear sequence of messenger RNAs but also on their folding into intricate secondary structures and on chemical modification of the RNA bases. These features, which are highly dynamic and interdependent, exert direct control over the transcriptome thereby influencing many aspects of cell function. Here, we consider that coupling of RNA modifications and structure actively shapes RNA-protein interactions through individual steps of gene expression.

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“…An eukaryotic mRNA is canonically viewed as divided into four functional segments: the 5′ UTR (including the m 7 G cap), the coding sequence, the 3′ UTR, and the poly(A) tail . Incorporating a fluorescent probe into any one of these segments may be deleterious to the mRNA's function, potentially resulting in spurious findings and incorrect conclusions.…”

Section: Introductionmentioning

confidence: 99%

In vitro labeling strategies for in cellulo fluorescence microscopy of single ribonucleoprotein machines

Custer

Walter

2017

Protein Science

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RNA plays a fundamental, ubiquitous role as either substrate or functional component of many large cellular complexes-"molecular machines"-used to maintain and control the readout of genetic information, a functional landscape that we are only beginning to understand. The cellular mechanisms for the spatiotemporal organization of the plethora of RNAs involved in gene expression are particularly poorly understood. Intracellular single-molecule fluorescence microscopy provides a powerful emerging tool for probing the pertinent mechanistic parameters that govern cellular RNA functions, including those of protein coding messenger RNAs (mRNAs). Progress has been hampered, however, by the scarcity of efficient high-yield methods to fluorescently label RNA molecules without the need to drastically increase their molecular weight through artificial appendages that may result in altered behavior. Herein, we employ T7 RNA polymerase to body label an RNA with a cyanine dye, as well as yeast poly(A) polymerase to strategically place multiple 2'-azido-modifications for subsequent fluorophore labeling either between the body and tail or randomly throughout the tail. Using a combination of biochemical and single-molecule fluorescence microscopy approaches, we demonstrate that both yeast poly(A) polymerase labeling strategies result in fully functional mRNA, whereas protein coding is severely diminished in the case of body labeling.

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Regulatory effects of cotranscriptional RNA structure formation and transitions

Cited by 22 publications

References 88 publications

Splicing and transcription touch base: co-transcriptional spliceosome assembly and function

Splicing and transcription touch base: co-transcriptional spliceosome assembly and function

RNA modifications and structures cooperate to guide RNA–protein interactions

In vitro labeling strategies for in cellulo fluorescence microscopy of single ribonucleoprotein machines

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