A two-dimensional mutate-and-map strategy for non-coding RNA structure
Non-coding RNAs fold into precise base-pairing patterns to carry out critical roles in genetic regulation and protein synthesis, but determining RNA structure remains difficult. Here, we show that coupling systematic mutagenesis with high-throughput chemical mapping enables accurate base-pair infere...
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| Published in | Nature chemistry Vol. 3; no. 12; pp. 954 - 962 |
|---|---|
| Main Authors | , , , |
| Format | Journal Article |
| Language | English |
| Published |
London
Nature Publishing Group UK
01.12.2011
Nature Publishing Group |
| Subjects | |
| Online Access | Get full text |
| ISSN | 1755-4330 1755-4349 1755-4349 |
| DOI | 10.1038/nchem.1176 |
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| Abstract | Non-coding RNAs fold into precise base-pairing patterns to carry out critical roles in genetic regulation and protein synthesis, but determining RNA structure remains difficult. Here, we show that coupling systematic mutagenesis with high-throughput chemical mapping enables accurate base-pair inference of domains from ribosomal RNA, ribozymes and riboswitches. For a six-RNA benchmark that has challenged previous chemical/computational methods, this ‘mutate-and-map’ strategy gives secondary structures that are in agreement with crystallography (helix error rates, 2%), including a blind test on a double-glycine riboswitch. Through modelling of partially ordered states, the method enables the first test of an interdomain helix-swap hypothesis for ligand-binding cooperativity in a glycine riboswitch. Finally, the data report on tertiary contacts within non-coding RNAs, and coupling to the Rosetta/FARFAR algorithm gives nucleotide-resolution three-dimensional models (helix root-mean-squared deviation, 5.7 Å) of an adenine riboswitch. These results establish a promising two-dimensional chemical strategy for inferring the secondary and tertiary structures that underlie non-coding RNA behaviour.
Non-coding RNAs are ubiquitous biomolecules with intricate three-dimensional folds that are difficult to characterize. This Article presents an information-rich strategy for inferring RNA structure by combining nucleotide-by-nucleotide mutagenesis with single-nucleotide-resolution chemical mapping. |
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| AbstractList | Non-coding RNAs fold into precise base-pairing patterns to carry out critical roles in genetic regulation and protein synthesis, but determining RNA structure remains difficult. Here, we show that coupling systematic mutagenesis with high-throughput chemical mapping enables accurate base-pair inference of domains from ribosomal RNA, ribozymes and riboswitches. For a six-RNA benchmark that has challenged previous chemical/computational methods, this 'mutate-and-map' strategy gives secondary structures that are in agreement with crystallography (helix error rates, 2%), including a blind test on a double-glycine riboswitch. Through modelling of partially ordered states, the method enables the first test of an interdomain helix-swap hypothesis for ligand-binding cooperativity in a glycine riboswitch. Finally, the data report on tertiary contacts within non-coding RNAs, and coupling to the Rosetta/FARFAR algorithm gives nucleotide-resolution three-dimensional models (helix root-mean-squared deviation, 5.7 Å) of an adenine riboswitch. These results establish a promising two-dimensional chemical strategy for inferring the secondary and tertiary structures that underlie non-coding RNA behaviour. Non-coding RNAs fold into precise base-pairing patterns to carry out critical roles in genetic regulation and protein synthesis, but determining RNA structure remains difficult. Here, we show that coupling systematic mutagenesis with high-throughput chemical mapping enables accurate base-pair inference of domains from ribosomal RNA, ribozymes and riboswitches. For a six-RNA benchmark that has challenged previous chemical/computational methods, this ‘mutate-and-map’ strategy gives secondary structures that are in agreement with crystallography (helix error rates, 2%), including a blind test on a double-glycine riboswitch. Through modelling of partially ordered states, the method enables the first test of an interdomain helix-swap hypothesis for ligand-binding cooperativity in a glycine riboswitch. Finally, the data report on tertiary contacts within non-coding RNAs, and coupling to the Rosetta/FARFAR algorithm gives nucleotide-resolution three-dimensional models (helix root-mean-squared deviation, 5.7 Å) of an adenine riboswitch. These results establish a promising two-dimensional chemical strategy for inferring the secondary and tertiary structures that underlie non-coding RNA behaviour. Non-coding RNAs are ubiquitous biomolecules with intricate three-dimensional folds that are difficult to characterize. This Article presents an information-rich strategy for inferring RNA structure by combining nucleotide-by-nucleotide mutagenesis with single-nucleotide-resolution chemical mapping. Non-coding RNAs fold into precise base-pairing patterns to carry out critical roles in genetic regulation and protein synthesis, but determining RNA structure remains difficult. Here, we show that coupling systematic mutagenesis with high-throughput chemical mapping enables accurate base-pair inference of domains from ribosomal RNA, ribozymes and riboswitches. For a six-RNA benchmark that has challenged previous chemical/computational methods, this 'mutate-and-map' strategy gives secondary structures that are in agreement with crystallography (helix error rates, 2%), including a blind test on a double-glycine riboswitch. Through modelling of partially ordered states, the method enables the first test of an interdomain helix-swap hypothesis for ligand-binding cooperativity in a glycine riboswitch. Finally, the data report on tertiary contacts within non-coding RNAs, and coupling to the Rosetta/FARFAR algorithm gives nucleotide-resolution three-dimensional models (helix root-mean-squared deviation, 5.7 Aa) of an adenine riboswitch. These results establish a promising two-dimensional chemical strategy for inferring the secondary and tertiary structures that underlie non-coding RNA behaviour. Non-coding RNAs fold into precise base-pairing patterns to carry out critical roles in genetic regulation and protein synthesis, but determining RNA structure remains difficult. Here, we show that coupling systematic mutagenesis with high-throughput chemical mapping enables accurate base-pair inference of domains from ribosomal RNA, ribozymes and riboswitches. For a six-RNA benchmark that has challenged previous chemical/computational methods, this 'mutate-and-map' strategy gives secondary structures that are in agreement with crystallography (helix error rates, 2%), including a blind test on a double-glycine riboswitch. Through modelling of partially ordered states, the method enables the first test of an interdomain helix-swap hypothesis for ligand-binding cooperativity in a glycine riboswitch. Finally, the data report on tertiary contacts within non-coding RNAs, and coupling to the Rosetta/FARFAR algorithm gives nucleotide-resolution three-dimensional models (helix root-mean-squared deviation, 5.7 Å) of an adenine riboswitch. These results establish a promising two-dimensional chemical strategy for inferring the secondary and tertiary structures that underlie non-coding RNA behaviour.Non-coding RNAs fold into precise base-pairing patterns to carry out critical roles in genetic regulation and protein synthesis, but determining RNA structure remains difficult. Here, we show that coupling systematic mutagenesis with high-throughput chemical mapping enables accurate base-pair inference of domains from ribosomal RNA, ribozymes and riboswitches. For a six-RNA benchmark that has challenged previous chemical/computational methods, this 'mutate-and-map' strategy gives secondary structures that are in agreement with crystallography (helix error rates, 2%), including a blind test on a double-glycine riboswitch. Through modelling of partially ordered states, the method enables the first test of an interdomain helix-swap hypothesis for ligand-binding cooperativity in a glycine riboswitch. Finally, the data report on tertiary contacts within non-coding RNAs, and coupling to the Rosetta/FARFAR algorithm gives nucleotide-resolution three-dimensional models (helix root-mean-squared deviation, 5.7 Å) of an adenine riboswitch. These results establish a promising two-dimensional chemical strategy for inferring the secondary and tertiary structures that underlie non-coding RNA behaviour. |
| Author | Cordero, Pablo Das, Rhiju Kladwang, Wipapat VanLang, Christopher C. |
| AuthorAffiliation | 1 Department of Biochemistry, Stanford University, Stanford, California 94305, USA 4 Department of Physics, Stanford University, Stanford, California 94305, USA 3 Program in Biomedical Informatics, Stanford University, Stanford, California 94305, USA 2 Department of Chemical Engineering, Stanford University, Stanford, California 94305, USA |
| AuthorAffiliation_xml | – name: 3 Program in Biomedical Informatics, Stanford University, Stanford, California 94305, USA – name: 1 Department of Biochemistry, Stanford University, Stanford, California 94305, USA – name: 4 Department of Physics, Stanford University, Stanford, California 94305, USA – name: 2 Department of Chemical Engineering, Stanford University, Stanford, California 94305, USA |
| Author_xml | – sequence: 1 givenname: Wipapat surname: Kladwang fullname: Kladwang, Wipapat organization: Department of Biochemistry, Stanford University – sequence: 2 givenname: Christopher C. surname: VanLang fullname: VanLang, Christopher C. organization: Department of Chemical Engineering, Stanford University – sequence: 3 givenname: Pablo surname: Cordero fullname: Cordero, Pablo organization: Program in Biomedical Informatics, Stanford University – sequence: 4 givenname: Rhiju surname: Das fullname: Das, Rhiju email: rhiju@stanford.edu organization: Department of Biochemistry, Stanford University, Program in Biomedical Informatics, Stanford University, Department of Physics, Stanford University |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/22109276$$D View this record in MEDLINE/PubMed |
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| Copyright | Springer Nature Limited 2011 Copyright Nature Publishing Group Dec 2011 2011 Macmillan Publishers Limited. All rights reserved. 2011 |
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| Snippet | Non-coding RNAs fold into precise base-pairing patterns to carry out critical roles in genetic regulation and protein synthesis, but determining RNA structure... |
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| SubjectTerms | 631/337/384 639/638/45/535 639/638/92 Accuracy Algorithms Analytical Chemistry Biochemistry Chemistry Chemistry and Materials Science Chemistry/Food Science Crystallography Glycine - chemistry Hypotheses Inorganic Chemistry Models, Molecular Mutation NMR Nuclear magnetic resonance Nucleic Acid Conformation Organic Chemistry Physical Chemistry Protein synthesis Riboswitch RNA, Untranslated - chemistry |
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| Title | A two-dimensional mutate-and-map strategy for non-coding RNA structure |
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