The increasing complexity of models for prediction of the native spatial structure of RNA molecules requires visualization methods that help to analyze and understand the models and their predictions. This paper improves the visualization method for sequences of barrier trees previously published by the authors. The barrier trees of these sequences are rough topological simplifications of changing folding landscapes – energy landscapes in which kinetic folding takes place. The folding landscapes themselves are generated for RNA molecules where the number of nucleotides increases. Successive landscapes are thus correlated and so are the corresponding barrier trees. The landscape sequence is visualized by an animation of a barrier tree that c...
Nucleic acids play vital roles in the cell by virtue of the information encoded into their nucleotid...
We introduce a method for predicting RNA folding pathways, with an application to the most important...
Background: Accurately predicting low energy barrier folding pathways between conformational seconda...
Dynamical models that explain the formation of spatial structures of RNA molecules have reached a co...
The increasing complexity of models for prediction of the native spatial structure of RNA molecules ...
Abstract: The analysis of RNA folding landscapes yields insights into the kinetic fold-ing behavior ...
A tool for a thorough investigation of RNA energy landscapes is presented. The topological details o...
Motivation: The function of an RNA molecule is not only linked to its native structure, which is usu...
Motivation: RNA folding is a complicated kinetic process. The minimum free energy structure provides...
The folding of biopolymers is crucially determined by the properties and the topology of the underly...
Motivation: Energy landscapes provide a valuable means for studying the folding dynamics of short RN...
Barrier trees consisting of local minima and their connecting saddle points imply a natural coarse-g...
Many research aim to RNA molecules and demand for tools enabling their analysis increased. First ste...
In molecular biology, the secondary structure of a ribonucleic acid (RNA) molecule is closely relate...
Dynamical changes of RNA secondary structures play an important role in the function of many regulat...
Nucleic acids play vital roles in the cell by virtue of the information encoded into their nucleotid...
We introduce a method for predicting RNA folding pathways, with an application to the most important...
Background: Accurately predicting low energy barrier folding pathways between conformational seconda...
Dynamical models that explain the formation of spatial structures of RNA molecules have reached a co...
The increasing complexity of models for prediction of the native spatial structure of RNA molecules ...
Abstract: The analysis of RNA folding landscapes yields insights into the kinetic fold-ing behavior ...
A tool for a thorough investigation of RNA energy landscapes is presented. The topological details o...
Motivation: The function of an RNA molecule is not only linked to its native structure, which is usu...
Motivation: RNA folding is a complicated kinetic process. The minimum free energy structure provides...
The folding of biopolymers is crucially determined by the properties and the topology of the underly...
Motivation: Energy landscapes provide a valuable means for studying the folding dynamics of short RN...
Barrier trees consisting of local minima and their connecting saddle points imply a natural coarse-g...
Many research aim to RNA molecules and demand for tools enabling their analysis increased. First ste...
In molecular biology, the secondary structure of a ribonucleic acid (RNA) molecule is closely relate...
Dynamical changes of RNA secondary structures play an important role in the function of many regulat...
Nucleic acids play vital roles in the cell by virtue of the information encoded into their nucleotid...
We introduce a method for predicting RNA folding pathways, with an application to the most important...
Background: Accurately predicting low energy barrier folding pathways between conformational seconda...