Superior cellular activities of azido- over amino-functionalized ligands for engineered preQ<sub>1</sub>riboswitches in<i>E.coli</i>

Neuner, Eva; Frener, Marina; Lusser, Alexandra; Micura, Ronald

doi:10.1080/15476286.2018.1534526

Cited by 13 publications

(9 citation statements)

References 51 publications

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“…Finally, it should be noted that riboswitches using a triple helix as a ligand‐binding site are not coupled to a single mechanism for controlling gene expression. The ligand‐bound forms of the c‐di‐GMP‐II (Lee et al, 2010) and guanidine‐III (Sherlock & Breaker, 2017) riboswitches turn ON translation while PreQ 1 ‐II (Dutta, Belashov, & Wedekind, 2018; Meyer et al, 2008; Neuner, Frener, Lusser, & Micura, 2018; Van Vlack, Topp, & Seeliger, 2017), PreQ 1 ‐III (Liberman et al, 2015; Van Vlack et al, 2017), metX SAM‐II (Gilbert et al, 2008), and SAM‐V riboswitches (L. Huang & Lilley, 2018; Poiata et al, 2009) turn OFF translation. Thus, there are instances where ligand binding leads to sequestration of the ribosome‐binding site into a triple helix to turn OFF translation and other instances where the ribosome‐binding site is released upon ligand binding, thereby turning ON translation.…”

Section: Structure and Function Of Natural Rna Triple Helicesmentioning

confidence: 99%

Unraveling the structure and biological functions of RNA triple helices

Brown

2020

WIREs RNA

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It has been nearly 63 years since the first characterization of an RNA triple helix in vitro by Gary Felsenfeld, David Davies, and Alexander Rich. An RNA triple helix consists of three strands: A Watson-Crick RNA double helix whose major-groove establishes hydrogen bonds with the so-called "third strand". In the past 15 years, it has been recognized that these major-groove RNA triple helices, like single-stranded and double-stranded RNA, also mediate prominent biological roles inside cells. Thus far, these triple helices are known to mediate catalysis during telomere synthesis and RNA splicing, bind to ligands and ions so that metabolite-sensing riboswitches can regulate gene expression, and provide a clever strategy to protect the 3 0 end of RNA from degradation. Because RNA triple helices play important roles in biology, there is a renewed interest in better understanding the fundamental properties of RNA triple helices and developing methods for their high-throughput discovery. This review provides an overview of the fundamental biochemical and structural properties of major-groove RNA triple helices, summarizes the structure and function of naturally occurring RNA triple helices, and describes prospective strategies to isolate RNA triple helices as a means to establish the "triplexome".

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Section: Structure and Function Of Natural Rna Triple Helicesmentioning

confidence: 99%

Unraveling the structure and biological functions of RNA triple helices

Brown

2020

WIREs RNA

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“…Finally, Carell reported a cycloaddition route relying on α-brominated 3-phthalimidopropanal and diaminopyrimidin-4-one [ 24 – 25 ]. We further optimized this path for the synthesis of 15 N-labeled prequeuosine nucleobase derivatives [ 26 ] required for advanced NMR spectroscopic applications [ 27 ], and for the syntheses of azido- or amino-functionalized preQ 1 derivatives needed for cellular applications with engineered riboswitches [ 28 ]. Finally, we point out that only a single synthetic route has been published to a potential O 6 -methylated precursor of m 6 preQ 1 , namely N 9-trimethysilylethyl protected m 6 preQ 0 [ 20 ].…”

Section: Resultsmentioning

confidence: 99%

“…vanced NMR spectroscopic applications [27], and for the syntheses of azido-or amino-functionalized preQ 1 derivatives needed for cellular applications with engineered riboswitches [28]. Finally, we point out that only a single synthetic route has been published to a potential O 6 -methylated precursor of m 6 preQ 1 , namely N9-trimethysilylethyl protected m 6 preQ 0 [20].…”

Section: Natural Occurrence Of Alkylated Prequeuosinesmentioning

confidence: 99%

Synthesis of O⁶-alkylated preQ₁ derivatives

Flemmich

Moreno

Micura

2021

Beilstein J. Org. Chem.

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A naturally occurring riboswitch can utilize 7-aminomethyl-O6-methyl-7-deazaguanine (m6preQ1) as cofactor for methyl group transfer resulting in cytosine methylation. This recently discovered riboswitch-ribozyme activity opens new avenues for the development of RNA labeling tools based on tailored O6-alkylated preQ1 derivatives. Here, we report a robust synthesis for this class of pyrrolo[2,3-d]pyrimidines starting from readily accessible N2-pivaloyl-protected 6-chloro-7-cyano-7-deazaguanine. Substitution of the 6-chloro atom with the alcoholate of interest proceeds straightforward. The transformation of the 7-cyano substituent into the required aminomethyl group turned out to be challenging and was solved by a hydration reaction sequence on a well-soluble dimethoxytritylated precursor via in situ oxime formation. The synthetic path now provides a solid foundation to access O6-alkylated 7-aminomethyl-7-deazaguanines for the development of RNA labeling tools based on the preQ1 class-I riboswitch scaffold.

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“…Oligoribonucleotides carrying site-specific modifications are highly required as models for structure and function studies, driven by the ongoing discovery of new RNAs and their investigation [1][2][3][4][5][6]. This has put demand also on synthetic chemistry to provide suitable compounds at monomeric and oligomeric level.…”

Section: Introductionmentioning

confidence: 99%

Changed reactivity of secondary hydroxy groups in C8-modified adenosine – lessons learned from silylation

Frommer

Müller

2020

Beilstein J. Org. Chem.

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Synthesis of site-specifically modified oligonucleotides has become a major tool for RNA structure and function studies. Reporter groups or specific functional entities are required to be attached at a pre-defined site of the oligomer. An attractive strategy is the incorporation of suitably functionalized building blocks that allow post-synthetic conjugation of the desired moiety. A C8-alkynyl-modified adenosine derivative was synthesized, reviving an old synthetic pathway for iodination of purine nucleobases. Silylation of the C8-alkynyl-modified adenosine revealed unexpected selectivity of the two secondary sugar hydroxy groups, with the 3'-O-isomer being preferentially formed. Optimization of the protection scheme lead to a new and economic route to the desired C8-alkynylated building block and its incorporation in RNA.

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Superior cellular activities of azido- over amino-functionalized ligands for engineered preQ₁riboswitches inE.coli

Cited by 13 publications

References 51 publications

Unraveling the structure and biological functions of RNA triple helices

Unraveling the structure and biological functions of RNA triple helices

Synthesis of O⁶-alkylated preQ₁ derivatives

Changed reactivity of secondary hydroxy groups in C8-modified adenosine – lessons learned from silylation

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Superior cellular activities of azido- over amino-functionalized ligands for engineered preQ1riboswitches inE.coli

Cited by 13 publications

References 51 publications

Unraveling the structure and biological functions of RNA triple helices

Unraveling the structure and biological functions of RNA triple helices

Synthesis of O6-alkylated preQ1 derivatives

Changed reactivity of secondary hydroxy groups in C8-modified adenosine – lessons learned from silylation

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Superior cellular activities of azido- over amino-functionalized ligands for engineered preQ₁riboswitches inE.coli

Synthesis of O⁶-alkylated preQ₁ derivatives