Screening for engineered neomycin riboswitches that control translation initiation

Weigand, Julia E.; Sanchez, Martin; Gunnesch, Ewald Bernd; Zeiher, Sabrina; Schroeder, Renée; Suess, Beatrix

doi:10.1261/rna.772408

Cited by 187 publications

(226 citation statements)

References 41 publications

(61 reference statements)

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“…Previous work has revealed that bacterial riboswitches that act on a translational level often regulate gene expression through ligand-dependent structural changes in the 59-UTR that provide or limit access to the ribosome binding site (RBS) of an RNA transcript (Nudler and Mironov 2004). This insight has inspired efforts to convert synthetic aptamers into riboswitches through rational engineering (Werstuck and Green 1998;Desai and Gallivan 2004;Suess 2005) or genetic screens and selections (Lynch et al 2007;Topp and Gallivan 2008;Weigand et al 2008). Here, we report that synthetic riboswitches that modulate translation in bacteria can be located within the coding region of a gene and that opportunities for developing new riboswitches may be enhanced by placing fewer restrictions on the expected mechanisms of RNA-based genetic regulation.…”

Section: Introductionmentioning

confidence: 99%

Riboswitches in unexpected places—A synthetic riboswitch in a protein coding region

Topp

Gallivan²

2008

RNA

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In natural and engineered systems, cis-RNA regulatory elements such as riboswitches are typically found within untranslated regions rather than within the protein coding sequences of genes. However, RNA sequences with important regulatory roles can exist within translated regions. Here, we present a synthetic riboswitch that is encoded within the translated region of a gene and represses Escherichia coli gene expression greater than 25-fold in the presence of a small-molecule ligand. The ability to encode riboswitches within translated regions as well as untranslated regions provides additional opportunities for creating new genetic control elements. Furthermore, evidence that a riboswitch can function in the translated region of a gene suggests that future efforts to identify natural riboswitches should consider this possibility.

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Section: Introductionmentioning

confidence: 99%

Riboswitches in unexpected places—A synthetic riboswitch in a protein coding region

Topp

Gallivan²

2008

RNA

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“…Notably, insertion of aptamers into the 5′-UTRs of bacterial or eukaryotic mRNAs (9)(10)(11)(12), splice sites within introns of eukaryotic pre-mRNA (13,14), or coupling of aptamers to ribozymes (15,16) have shown significant potential for small-molecule modulation of gene expression. However, there are currently very few aptamers, generated by in vitro selection, that are selective for ligands with desirable physicochemical and pharmacokinetic properties (8).…”

mentioning

confidence: 99%

Reengineering orthogonally selective riboswitches

Dixon

Duncan²,

Geerlings³

et al. 2010

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

151

163

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The ability to independently control the expression of multiple genes by addition of distinct small-molecule modulators has many applications from synthetic biology, functional genomics, pharmaceutical target validation, through to gene therapy. Riboswitches are relatively simple, small-molecule-dependent, protein-free, mRNA genetic switches that are attractive targets for reengineering in this context. Using a combination of chemical genetics and genetic selection, we have developed riboswitches that are selective for synthetic "nonnatural" small molecules and no longer respond to the natural intracellular ligands. The orthogonal selectivity of the riboswitches is also demonstrated in vitro using isothermal titration calorimetry and x-ray crystallography. The riboswitches allow highly responsive, dose-dependent, orthogonally selective, and dynamic control of gene expression in vivo. It is possible that this approach may be further developed to reengineer other natural riboswitches for application as small-molecule responsive genetic switches in both prokaryotes and eukaryotes.

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“…However, a major drawback in the analysis of large-scale metagenomic sequence data sets is the isolation of functional elements, given that these RNAs tend to: (1) be short (often mistaken for chemically degraded RNAs), (2) lack open reading frames, and (3) sometimes evolve rapidly at the sequence levels while still conserving structure that is integral to their function. 107,108 Need for novel in vitro RNA stabilization methods Although new sensing capabilities of natural and unnatural ligands have been successfully engineered into RNAs via in vitro and in vivo molecular evolution approaches, [109][110][111] the ability to use these molecules by incorporating them into more complex systems and devices represents a bigger practical challenge. 23 All potential RNA Synthetic Biology applications require reproducible and controlled molecular stability, especially when activity is required outside the native cellular host and in the context of other biological and inorganic materials.…”

Section: Unexplored Diversity Of Natural Riboswitches In Living Systemsmentioning

confidence: 99%

Regulatory RNAs

Vazquez-Anderson¹,

Contreras

2013

RNA Biology

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Screening for engineered neomycin riboswitches that control translation initiation

Cited by 187 publications

References 41 publications

Riboswitches in unexpected places—A synthetic riboswitch in a protein coding region

Riboswitches in unexpected places—A synthetic riboswitch in a protein coding region

Reengineering orthogonally selective riboswitches

Regulatory RNAs

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