Folding of noncoding RNAs during transcription facilitated by pausing-induced nonnative structures

Wong, Terrence N.; Sosnick, Tobin R.; Pan, Tao

doi:10.1073/pnas.0705038104

Cited by 118 publications

(127 citation statements)

References 33 publications

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“…This polarity-driven folding process is further controlled through the strategic location of transcriptional pause sites (46) that presumably allow sufficient time for secondary and tertiary interactions to take place. These interactions are often important for the folding of complex RNA structures (47,48). Transcriptional pausing has been identified in metabolite-binding riboswitches responsive to flavin mononucleotide (49), adenine (27), and AdoCbl (19) and in a pH-responsive riboregulator (50).…”

Section: Discussionmentioning

confidence: 99%

A Kissing Loop Is Important for btuB Riboswitch Ligand Sensing and Regulatory Control

Lussier

Bastet

Chauvier

et al. 2015

Journal of Biological Chemistry

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Background:The btuB riboswitch contains an unusual kissing loop structure that exhibits few interactions with bound adenosylcobalamin. Results: Structural probing and in vivo analysis show that kissing loop mutations strongly uncouple ligand binding from riboswitch regulation. Conclusion:The kissing loop is pivotal for coordinating riboswitch conformational changes. Significance: In contrast to most riboswitches, btuB relies on a kissing loop to achieve both metabolite sensing and gene regulation.

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Section: Discussionmentioning

confidence: 99%

A Kissing Loop Is Important for btuB Riboswitch Ligand Sensing and Regulatory Control

Lussier

Bastet

Chauvier

et al. 2015

Journal of Biological Chemistry

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“…In a cellular context, furthermore, the nascent RNA molecule starts to fold before the transcription process is completed. Co-transcriptional folding is strongly affected by the speed of elongation, sitespecific pausing of the RNA polymerase and interactions of the nascent RNA molecule with proteins or small-molecule metabolites (1), (2). Since transcription is a sequential process, the 5' region of a native helix is synthesized before its 3' portion.…”

Section: Introductionmentioning

confidence: 99%

Folding Kinetics of Large RNAs

Geis

Flamm

Wolfinger

et al. 2008

Journal of Molecular Biology

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We introduce here a heuristic approach to kinetic RNA folding that constructs secondary structures by stepwise combination of building blocks. These blocks correspond to sub-sequences and their thermodynamically optimal structures. These are determined by the standard dynamic programming approach to RNA folding. Folding trajectories are modeled at base pair resolution using the Morgan-Higgs heuristic and a barrier tree based heuristic to connect combinations of the local building blocks. Implemented in the program Kinwalker, the algorithm allows cotranscriptional folding and can be used to fold sequences of up to about 1500 nucleotides in length. A detailed comparison with several well-studied examples from the literature, including the delayed folding of bacteriophage cloverleaf structures, the ASR riboswitch, and the Hok RNA, shows an excellent agreement of predicted trajectories and experimental evidence. The software is available as part of the Vienna RNA Package.

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“…RNAP pauses at strategic sites located downstream of the 5′ region of all long-range helices. These pauses enable nascent RNAs to fold into beneficial nonnative structures wherein the 5′ region is sequestered and poised for subsequent folding of the native structure (13). Second, riboswitch function involves two or more competing structures; one structure directly senses cellular metabolite concentration.…”

mentioning

confidence: 99%

Transcriptional pausing coordinates folding of the aptamer domain and the expression platform of a riboswitch

Perdrizet

Artsimovitch

Furman

et al. 2012

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

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100

124

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Riboswitches are cis-acting elements that regulate gene expression by affecting transcriptional termination or translational initiation in response to binding of a metabolite. A typical riboswitch is made of an upstream aptamer domain and a downstream expression platform. Both domains participate in the folding and structural rearrangement in the absence or presence of its cognate metabolite. RNA polymerase pausing is a fundamental property of transcription that can influence RNA folding. Here we show that pausing plays an important role in the folding and conformational rearrangement of the Escherichia coli btuB riboswitch during transcription by the E. coli RNA polymerase. This riboswitch consists of an approximately 200 nucleotide, coenzyme B12 binding aptamer domain and an approximately 40 nucleotide expression platform that controls the ribosome access for translational initiation. We found that transcriptional pauses at strategic locations facilitate folding and structural rearrangement of the full-length riboswitch, but have minimal effect on the folding of the isolated aptamer domain. Pausing at these regulatory sites blocks the formation of alternate structures and plays a chaperoning role that couples folding of the aptamer domain and the expression platform. Pausing at strategic locations may be a general mechanism for coordinated folding and conformational rearrangements of riboswitch structures that underlie their response to environmental cues.gene regulation | translational control | metabolism R NA structures fulfill important roles in the regulation of gene expression including the control of translational initiation, transcriptional termination, and alternative splicing (1-5). In many cases, an RNA conformational change is crucial to gene regulation since one RNA sequence may adopt alternate structures. Regulation of gene expression is achieved when an input domain senses varying cellular conditions, resulting in shifting the balance between two or more structural states.A prime example of gene regulation by RNA conformational changes in bacteria is riboswitch control. Riboswitches are cisacting elements that regulate gene expression in response to the concentration of an intracellular metabolite. The coenzyme B12 riboswitch is located in the 5′ untranslated region of the btuB gene which encodes an outer membrane transporter for B12 (6) (Fig. 1A). The btuB riboswitch consists of two domains: an upstream coenzyme B12 binding aptamer and a downstream expression platform. When the cellular concentration of coenzyme B12 is high, this metabolite binds to the aptamer, reconfiguring the expression platform to form a structure in which the ribosome binding site (RBS) is base paired and inaccessible. When the concentration of coenzyme B12 is low, the mRNA forms an alternate structure which allows for translation (6, 7).RNA folding and conformational switching occurs during transcription in vivo. Folding during transcription is particularly important for riboswitch regulation (8). Although bacterial RNA ...

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Folding of noncoding RNAs during transcription facilitated by pausing-induced nonnative structures

Cited by 118 publications

References 33 publications

A Kissing Loop Is Important for btuB Riboswitch Ligand Sensing and Regulatory Control

A Kissing Loop Is Important for btuB Riboswitch Ligand Sensing and Regulatory Control

Folding Kinetics of Large RNAs

Transcriptional pausing coordinates folding of the aptamer domain and the expression platform of a riboswitch

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