The biological functions of RNA are ultimately governed by the local environment at each nucleotide. Selective 2′-hydroxyl acylation analyzed by primer extension (SHAPE) chemistry is a powerful approach for measuring nucleotide structure and dynamics in diverse biological environments. SHAPE reagents acylate the 2′-hydroxyl group at flexible nucleotides because unconstrained nucleotides preferentially sample rare conformations that enhance the nucleophilicity of the 2′-hydroxyl. The critical corollary is that some constrained nucleotides must be poised for efficient reaction at the 2′-hydroxyl group. To identify such nucleotides, we performed SHAPE on intact crystals of the <i>Escherichia coli</i> ribosome, monitored the reactivity of 1490 ...
grantor: University of TorontoRNA is intimately involved in many vital biological processe...
RNA molecules undergo local conformational dynamics on timescales spanning picoseconds to minutes. S...
International audienceAs more sequencing data accumulate and novel puzzling genetic regulations are ...
The biological functions of RNA are ultimately governed by the local environment at each nucleotide....
RNA is central to the flow of biological information. From transcription to splicing, RNA localizati...
RNA is the central conduit for gene expression. This role depends on an ability to encode informatio...
The function of RNA molecules usually depends on their overall fold and on the presence of specific ...
The selective 2′-hydroxyl acylation analyzed by primer extension (SHAPE) method probes RNA local str...
The functions of most RNA molecules are critically dependent on the distinct local dynamics that cha...
RNA SHAPE chemistry yields quantitative, single nucleotide resolution structural information based o...
Many RNA structures are comprised of simple secondary structure elements linked by a few, critical, ...
RNA SHAPE chemistry exploits the discovery that conformationally dynamic nucleotides preferentially ...
Hydroxyl-selective electrophiles, including N-methylisatoic anhydride (NMIA) and 1-methyl-7-nitroisa...
SHAPE chemistries exploit small electrophilic reagents that react with the 2′-hydroxyl group to inte...
grantor: University of TorontoRNA is intimately involved in many vital biological processe...
RNA molecules undergo local conformational dynamics on timescales spanning picoseconds to minutes. S...
International audienceAs more sequencing data accumulate and novel puzzling genetic regulations are ...
The biological functions of RNA are ultimately governed by the local environment at each nucleotide....
RNA is central to the flow of biological information. From transcription to splicing, RNA localizati...
RNA is the central conduit for gene expression. This role depends on an ability to encode informatio...
The function of RNA molecules usually depends on their overall fold and on the presence of specific ...
The selective 2′-hydroxyl acylation analyzed by primer extension (SHAPE) method probes RNA local str...
The functions of most RNA molecules are critically dependent on the distinct local dynamics that cha...
RNA SHAPE chemistry yields quantitative, single nucleotide resolution structural information based o...
Many RNA structures are comprised of simple secondary structure elements linked by a few, critical, ...
RNA SHAPE chemistry exploits the discovery that conformationally dynamic nucleotides preferentially ...
Hydroxyl-selective electrophiles, including N-methylisatoic anhydride (NMIA) and 1-methyl-7-nitroisa...
SHAPE chemistries exploit small electrophilic reagents that react with the 2′-hydroxyl group to inte...
grantor: University of TorontoRNA is intimately involved in many vital biological processe...
RNA molecules undergo local conformational dynamics on timescales spanning picoseconds to minutes. S...
International audienceAs more sequencing data accumulate and novel puzzling genetic regulations are ...