Your search keyword '"Jose Laborde"' showing total 3 results

1. RASS: a web server for RNA alignment in the joint sequence-structure space

Author

Jinfeng Zhang, Jose Laborde, Gewen He, Albert Steppi, Anuj Srivastava, and Peixiang Zhao

Subjects

Web server, Internet, business.industry, Sequence analysis, Sequence Analysis, RNA, Structural alignment, RNA, Sequence alignment, Information needs, Biology, computer.software_genre, Bioinformatics, Article, Software, Genetics, Nucleic Acid Conformation, business, computer, Algorithm, Sequence Alignment, Shape analysis (digital geometry)

Abstract

Comparison of ribonucleic acid (RNA) molecules is important for revealing their evolutionary relationships, predicting their functions and predicting their structures. Many methods have been developed for comparing RNAs using either sequence or three-dimensional (3D) structure (backbone geometry) information. Sequences and 3D structures contain non-overlapping sets of information that both determine RNA functions. When comparing RNA 3D structures, both types of information need to be taken into account. However, few methods compare RNA structures using both sequence and 3D structure information. Recently, we have developed a new method based on elastic shape analysis (ESA) that compares RNA molecules by combining both sequence and 3D structure information. ESA treats RNA structures as 3D curves with sequence information encoded on additional coordinates so that the alignment can be performed in the joint sequence-structure space. The similarity between two RNA molecules is quantified by a formal distance, geodesic distance. In this study, we implement a web server for the method, called RASS, to make it publicly available to research community. The web server is located at http://cloud.stat.fsu.edu/RASS/.

Published

2014

2. Structure-based RNA Function Prediction Using Elastic Shape Analysis

Author

Jinfeng Zhang, Anuj Srivastava, and Jose Laborde

Subjects

Geodesic, Structural alignment, Molecular biophysics, Probability distribution, RNA, Biology, Nucleic acid structure, Elasticity (economics), Biological system, Bioinformatics, Shape analysis (digital geometry)

Abstract

In recent years, RNAs have been found to have diverse functions beyond being a messenger in gene transcription. The functions of non-coding RNAs are determined by their structures. Structure comparison/alignment of RNAs provides an effective means to predict their functions. Despite many previous studies on RNA structure alignment, it is still a challenging problem to predict the function of RNA molecules based on their structure information. In this study, we developed a new RNA structure alignment method based on elastic shape analysis (ESA). ESA treats RNA structures as three dimensional curves and performs flexible alignment between two RNA molecules by bending and stretching one of the molecules to match the other. The amount of bending and stretching is quantified by a formal distance, geodesic distance. Based on ESA, a rigorous mathematical framework can be built for RNA structure comparison. Means and covariances can be computed and probability distributions can be constructed for a group of RNA structures. We further applied the method to predict functions of RNA molecules. Our method achieved good performance when tested on benchmark datasets.

Published

2011

3. RNA global alignment in the joint sequence–structure space using elastic shape analysis

Author

Jinfeng Zhang, Anuj Srivastava, Eric Klassen, Jose Laborde, and Daniel Robinson

Subjects

0303 health sciences, Multiple sequence alignment, Sequence Analysis, RNA, Structural alignment, RNA, Sequence alignment, Biology, Bioinformatics, 03 medical and health sciences, 0302 clinical medicine, Protein structure, Genetics, Methods Online, Nucleic Acid Conformation, Nucleic acid structure, Biological system, Sequence Alignment, 030217 neurology & neurosurgery, Alignment-free sequence analysis, 030304 developmental biology, Shape analysis (digital geometry)

Abstract

The functions of RNAs, like proteins, are determined by their structures, which, in turn, are determined by their sequences. Comparison/alignment of RNA molecules provides an effective means to predict their functions and understand their evolutionary relationships. For RNA sequence alignment, most methods developed for protein and DNA sequence alignment can be directly applied. RNA 3-dimensional structure alignment, on the other hand, tends to be more difficult than protein structure alignment due to the lack of regular secondary structures as observed in proteins. Most of the existing RNA 3D structure alignment methods use only the backbone geometry and ignore the sequence information. Using both the sequence and backbone geometry information in RNA alignment may not only produce more accurate classification, but also deepen our understanding of the sequence-structure-function relationship of RNA molecules. In this study, we developed a new RNA alignment method based on elastic shape analysis (ESA). ESA treats RNA structures as three dimensional curves with sequence information encoded on additional dimensions so that the alignment can be performed in the joint sequence-structure space. The similarity between two RNA molecules is quantified by a formal distance, geodesic distance. Based on ESA, a rigorous mathematical framework can be built for RNA structure comparison. Means and covariances of full structures can be defined and computed, and probability distributions on spaces of such structures can be constructed for a group of RNAs. Our method was further applied to predict functions of RNA molecules and showed superior performance compared with previous methods when tested on benchmark datasets. The programs are available at http://stat.fsu.edu/ ∼jinfeng/ESA.html.

Published

2013