KGSrna: efficient 3D kinematics-based sampling for nucleic acids

Rasmus Fonseca; Henry van den Bedem; Julie Bernauer

doi:10.1007/978-3-319-16706-0_11

KGSrna: efficient 3D kinematics-based sampling for nucleic acids

Rasmus Fonseca, Henry van den Bedem, Julie Bernauer

Datalogisk Institut

5 Citationer (Scopus)

Abstract

Noncoding ribonucleic acids (RNA) play a critical role in a wide variety of cellular processes, ranging from regulating gene expression to post-translational modification and protein synthesis. Their activity is modulated by highly dynamic exchanges between three-dimensional conformational substates, which are difficult to characterize experimentally and computationally. Here, we present an innovative, entirely kinematic computational procedure to efficiently explore the native ensemble of RNA molecules. Our procedure projects degrees of freedom onto a subspace of conformation space defined by distance constraints in the tertiary structure. The dimensionality reduction enables efficient exploration of conformational space. We show that the conformational distributions obtained with our method broadly sample the conformational landscape observed in NMR experiments. Compared to normal mode analysis-based exploration, our procedure diffuses faster through the experimental ensemble while also accessing conformational substates to greater precision. Our results suggest that conformational sampling with a highly reduced but fully atomistic representation of noncoding RNA expresses key features of their dynamic nature.

Originalsprog	Engelsk
Titel	Research in Computational Molecular Biology : 19th Annual International Conference, RECOMB 2015, Warsaw, Poland, April 12-15, 2015, Proceedings
Redaktører	Teresa Przytycka
Antal sider	16
Forlag	Springer
Publikationsdato	2015
Sider	80-95
ISBN (Trykt)	978-3-319-16705-3
ISBN (Elektronisk)	978-3-319-16706-0
DOI	https://doi.org/10.1007/978-3-319-16706-0_11
Status	Udgivet - 2015
Begivenhed	Annual International Conference, RECOMB 2015 - Warsaw, Polen Varighed: 12 apr. 2015 → 15 apr. 2015 Konferencens nummer: 19

Konference

Konference	Annual International Conference, RECOMB 2015
Nummer	19
Land/Område	Polen
By	Warsaw
Periode	12/04/2015 → 15/04/2015

Navn	Lecture Notes in Bioinformatics
ISSN	1611-3349

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10.1007/978-3-319-16706-0_11

Citationsformater

Fonseca, R., van den Bedem, H., & Bernauer, J. (2015). KGSrna: efficient 3D kinematics-based sampling for nucleic acids. I T. Przytycka (red.), Research in Computational Molecular Biology: 19th Annual International Conference, RECOMB 2015, Warsaw, Poland, April 12-15, 2015, Proceedings (s. 80-95). Springer. Lecture Notes in Bioinformatics https://doi.org/10.1007/978-3-319-16706-0_11

KGSrna : efficient 3D kinematics-based sampling for nucleic acids. / Fonseca, Rasmus; van den Bedem, Henry; Bernauer, Julie.

Research in Computational Molecular Biology: 19th Annual International Conference, RECOMB 2015, Warsaw, Poland, April 12-15, 2015, Proceedings. red. / Teresa Przytycka. Springer, 2015. s. 80-95 (Lecture Notes in Bioinformatics).

Publikation: Bidrag til bog/antologi/rapport › Konferencebidrag i proceedings › Forskning › peer review

Fonseca, R, van den Bedem, H & Bernauer, J 2015, KGSrna: efficient 3D kinematics-based sampling for nucleic acids. i T Przytycka (red.), Research in Computational Molecular Biology: 19th Annual International Conference, RECOMB 2015, Warsaw, Poland, April 12-15, 2015, Proceedings. Springer, Lecture Notes in Bioinformatics, s. 80-95, Annual International Conference, RECOMB 2015, Warsaw, Polen, 12/04/2015. https://doi.org/10.1007/978-3-319-16706-0_11

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abstract = "Noncoding ribonucleic acids (RNA) play a critical role in a wide variety of cellular processes, ranging from regulating gene expression to post-translational modification and protein synthesis. Their activity is modulated by highly dynamic exchanges between three-dimensional conformational substates, which are difficult to characterize experimentally and computationally. Here, we present an innovative, entirely kinematic computational procedure to efficiently explore the native ensemble of RNA molecules. Our procedure projects degrees of freedom onto a subspace of conformation space defined by distance constraints in the tertiary structure. The dimensionality reduction enables efficient exploration of conformational space. We show that the conformational distributions obtained with our method broadly sample the conformational landscape observed in NMR experiments. Compared to normal mode analysis-based exploration, our procedure diffuses faster through the experimental ensemble while also accessing conformational substates to greater precision. Our results suggest that conformational sampling with a highly reduced but fully atomistic representation of noncoding RNA expresses key features of their dynamic nature.",

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doi = "10.1007/978-3-319-16706-0_11",

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AB - Noncoding ribonucleic acids (RNA) play a critical role in a wide variety of cellular processes, ranging from regulating gene expression to post-translational modification and protein synthesis. Their activity is modulated by highly dynamic exchanges between three-dimensional conformational substates, which are difficult to characterize experimentally and computationally. Here, we present an innovative, entirely kinematic computational procedure to efficiently explore the native ensemble of RNA molecules. Our procedure projects degrees of freedom onto a subspace of conformation space defined by distance constraints in the tertiary structure. The dimensionality reduction enables efficient exploration of conformational space. We show that the conformational distributions obtained with our method broadly sample the conformational landscape observed in NMR experiments. Compared to normal mode analysis-based exploration, our procedure diffuses faster through the experimental ensemble while also accessing conformational substates to greater precision. Our results suggest that conformational sampling with a highly reduced but fully atomistic representation of noncoding RNA expresses key features of their dynamic nature.

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KGSrna: efficient 3D kinematics-based sampling for nucleic acids

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