Sébastien H Eschbach, Elsa D M Hien, Tithi Ghosh, Anne-Marie Lamontagne, Daniel A Lafontaine
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Here, we study the ligand-dependent cotranscriptional folding of the FMN-sensing <i>ribB</i> riboswitch of <i>Escherichia coli</i> Using RNase H assays to study nascent <i>ribB</i> riboswitch transcripts, DNA probes targeting the P1 and sequestering stems indicate that FMN binding leads to the protection of these regions from RNase H cleavage, consistent with the riboswitch inhibiting translation initiation when bound to FMN. Our results show that ligand sensing is strongly affected by the position of elongating RNA polymerase, which is defining an FMN-binding transcriptional window that is bordered in its 3' extremity by a transcriptional pause site. Also, using successively overlapping DNA probes targeting a subdomain of the riboswitch, our data suggest the presence of a previously unsuspected helical region involving the 3' strand of the P1 stem. Our results show that this helical region is conserved across bacterial species, thus suggesting that this predicted structure, the anti*-P1 stem, is involved in the FMN-free conformation of the <i>ribB</i> riboswitch. 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引用次数: 0
摘要
核糖开关是与代谢物结合的 RNA 调节器,可在转录和翻译水平上调节基因表达。核糖开关调控的特点之一是在与代谢物结合时发生结构变化。虽然人们已经花了很多精力来描述代谢物如何被核糖开关识别,但关于配体如何在转录背景下进行感应的信息仍然相对较少。在这里,我们研究了大肠杆菌 FMN 传感 ribB 核糖开关的配体依赖性共转录折叠。利用 RNase H 检测法研究新生的 ribB 核糖开关转录本,以 P1 和螯合茎为目标的 DNA 探针表明,FMN 结合会导致这些区域免受 RNase H 的裂解,这与核糖开关在与 FMN 结合时抑制翻译启动是一致的。我们的研究结果表明,配体感应受延伸 RNA 聚合酶位置的强烈影响,延伸 RNA 聚合酶正在确定一个与 FMN 结合的转录窗口,该窗口的 3' 端与一个转录暂停位点接壤。此外,利用针对核糖开关亚域的连续重叠 DNA 探针,我们的数据表明,在 P1 茎的 3' 链上存在一个以前未曾发现的螺旋区域。我们的研究结果表明,这一螺旋区域在不同细菌物种中是保守的,从而表明这一预测结构,即抗*-P1茎,参与了 ribB 核糖开关的无 FMN 构象。总之,我们的研究进一步证明,核糖开关可能利用复杂的折叠策略在转录过程中进行代谢物感应。
The Escherichia coli ribB riboswitch senses flavin mononucleotide within a defined transcriptional window.
Riboswitches are metabolite-binding RNA regulators that modulate gene expression at the levels of transcription and translation. One of the hallmarks of riboswitch regulation is that they undergo structural changes upon metabolite binding. While a lot of effort has been put to characterize how the metabolite is recognized by the riboswitch, there is still relatively little information regarding how ligand sensing is performed within a transcriptional context. Here, we study the ligand-dependent cotranscriptional folding of the FMN-sensing ribB riboswitch of Escherichia coli Using RNase H assays to study nascent ribB riboswitch transcripts, DNA probes targeting the P1 and sequestering stems indicate that FMN binding leads to the protection of these regions from RNase H cleavage, consistent with the riboswitch inhibiting translation initiation when bound to FMN. Our results show that ligand sensing is strongly affected by the position of elongating RNA polymerase, which is defining an FMN-binding transcriptional window that is bordered in its 3' extremity by a transcriptional pause site. Also, using successively overlapping DNA probes targeting a subdomain of the riboswitch, our data suggest the presence of a previously unsuspected helical region involving the 3' strand of the P1 stem. Our results show that this helical region is conserved across bacterial species, thus suggesting that this predicted structure, the anti*-P1 stem, is involved in the FMN-free conformation of the ribB riboswitch. Overall, our study further demonstrates that intricate folding strategies may be used by riboswitches to perform metabolite sensing during the transcriptional process.
期刊介绍:
RNA is a monthly journal which provides rapid publication of significant original research in all areas of RNA structure and function in eukaryotic, prokaryotic, and viral systems. It covers a broad range of subjects in RNA research, including: structural analysis by biochemical or biophysical means; mRNA structure, function and biogenesis; alternative processing: cis-acting elements and trans-acting factors; ribosome structure and function; translational control; RNA catalysis; tRNA structure, function, biogenesis and identity; RNA editing; rRNA structure, function and biogenesis; RNA transport and localization; regulatory RNAs; large and small RNP structure, function and biogenesis; viral RNA metabolism; RNA stability and turnover; in vitro evolution; and RNA chemistry.