2008
DOI: 10.1073/pnas.0709032105
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Structural inference of native and partially folded RNA by high-throughput contact mapping

Abstract: The biological behaviors of ribozymes, riboswitches, and numerous other functional RNA molecules are critically dependent on their tertiary folding and their ability to sample multiple functional states. The conformational heterogeneity and partially folded nature of most of these states has rendered their characterization by high-resolution structural approaches difficult or even intractable. Here we introduce a method to rapidly infer the tertiary helical arrangements of large RNA molecules in their native a… Show more

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Cited by 80 publications
(91 citation statements)
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References 51 publications
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“…Instead, the approach herein enables a vastly larger number of participants to design and execute remote experiments in parallel, while machine learning algorithms sift through the community's catalog of hypotheses. This Massive Open Laboratory template could be generalized to a broad class of biomolecule design problems, including mechanistic dissection of current design rules (26), modeling of pseudoknots, engineering of RNA switches for cellular control (5,6), and 3D modeling and design, all assessed by high-throughput mapping (1,7,16,20,29,30). Other fields, such as taxonomy (31), astronomy (13), and neural mapping (32), are making pioneering efforts in internet-scale scientific discovery games.…”
Section: Discussionmentioning
confidence: 99%
“…Instead, the approach herein enables a vastly larger number of participants to design and execute remote experiments in parallel, while machine learning algorithms sift through the community's catalog of hypotheses. This Massive Open Laboratory template could be generalized to a broad class of biomolecule design problems, including mechanistic dissection of current design rules (26), modeling of pseudoknots, engineering of RNA switches for cellular control (5,6), and 3D modeling and design, all assessed by high-throughput mapping (1,7,16,20,29,30). Other fields, such as taxonomy (31), astronomy (13), and neural mapping (32), are making pioneering efforts in internet-scale scientific discovery games.…”
Section: Discussionmentioning
confidence: 99%
“…For small RNA molecules with lengths less than 30 nt, prediction accuracy of about 4 Å root-mean-square-deviation (RMSD) for the main chains can be achieved. The prediction accuracy of FARNA can be further improved by considering secondary and tertiary structure information [27]. Recently, Baker et al [28] improved FARNA into an all-atomic structure prediction method with high accuracy, FARFAR.…”
Section: Rna Secondary Structure Predictionmentioning
confidence: 99%
“…Experimental methods used to probe through-space distances, such as t-HRP (Das et al, 2008;Gherghe et al, 2009), cross-linking (Harris et al, 1994;Pinard et al, 2001;Yu et al, 2008), and FRET (Rueda et al, 2004), can give high-quality distance information. However, these techniques often require synthesis of specialized RNA constructs, careful controls for unintended structural perturbations, and complex approaches for data interpretation (Hajdin et al, 2010).…”
Section: Solvent Accessibilitymentioning
confidence: 99%
“…The solvent accessibility of individual nucleotides can also be explored by solution hydroxyl radical probing (HRP) experiments (Cate et al, 1996;Pastor et al, 2000;Tullius and Greenbaum, 2005). Incorporation of experimentally derived structural information with computational modeling can markedly reduce the allowed conformational space and thereby facilitate the computational prediction of native RNA ensembles (Das et al, 2008;Gherghe et al, 2009;Jonikas et al, 2009;Lavender et al, 2010;Yang et al, 2010;Yu et al, 2008).…”
mentioning
confidence: 99%
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