We present TT2NE, a new algorithm to predict RNA secondary structures with
pseudoknots. The method is based on a classification of RNA structures
according to their topological genus. TT2NE guarantees to find the minimum free
energy structure irrespectively of pseudoknot topology. This unique proficiency
is obtained at the expense of the maximum length of sequence that can be
treated but comparison with state-of-the-art algorithms shows that TT2NE is a
very powerful tool within its limits. Analysis of TT2NE's wrong predictions
sheds light on the need to study how sterical constraints limit the range of
pseudoknotted structures that can be formed from a given sequence. An
implementation of TT2NE on a public server can be found at
http://ipht.cea.fr/rna/tt2ne.php

Bailor

Bellaousov

Dirks

Doshi

Elliot

Friedman

Henri Orland

Lyngso

Mathews

McCaskill

Metzler

Michaël Bon

Nussinov

Orland

Pillsbury

Reeder

Rivas

Ruan

Shen

t'Hooft

Tinoco

Vernizzi

Zhao

Zuker

Nucleic Acids Research

English

arXiv

Crossref

TT2NE: a novel algorithm to predict RNA secondary structures with pseudoknots

International audienceWe present TT2NE, a new algorithm to predict RNA secondary structures with pseudoknots. The method is based on a classification of RNA structures according to their topological genus. TT2NE is guaranteed to find the minimum free energy structure regardless of pseudoknot topology. This unique proficiency is obtained at the expense of the maximum length of sequences that can be treated, but comparison with state-of-the-art algorithms shows that TT2NE significantly improves the quality of predictions. Analysis of TT2NE's incorrect predictions sheds light on the need to study how sterical constraints limit the range of pseudoknotted structures that can be formed from a given sequence. An implementation of TT2NE on a public server can be found at http://ipht.cea.fr/rna/tt2ne.php

Bon, Michaël

Orland, Henri

HAL: Hyper Article en Ligne

HAL-CEA

Algorithms for loop matchings.

Characterization of self-cleaving RNA sequences on the genome

How RNA folds.

Molecular Biology of RNA.

Most mammalian mRNAs are conserved targets of microRNAs.

Optimal computer folding of large RNA sequences using thermodynamics and auxiliary information.

RNA pseudoknot prediction in energy-based models.

The equilibrium partition function and base pair binding probabilities for RNA secondary structure.

Topology links RNA secondary structure with global conformation, dynamics, and adaptation.

https://cea.hal.science/cea-00666032v1/file/e93.full.pdf

TT2NE: A novel algorithm to predict RNA secondary structures with
  pseudoknots

TT2NE: A novel algorithm to predict RNA secondary structures with pseudoknots

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