Article | REF: BIO7060 V1

Structural Bioinformatics - Database and prediction methods

Author: Catherine ETCHEBEST

Publication date: May 10, 2016

You do not have access to this resource.
Click here to request your free trial access!

Already subscribed? Log in!


Overview

Français

ABSTRACT

This article presents different bioinformatics approaches dedicated to the analysis and prediction of 3D structures of biological macromolecules, proteins and nucleic acids. It underlines the importance of 3D structures in understanding the function of these macromolecules, and the usefulness of 3D structural prediction methods. It provides information to help gain a better understanding of the main structural bioinformatics methods, and makes recommendation to implement an appropriate prediction strategy. With this aim, an array of tools and databases is suggested, supported by a recent bibliography.

Read this article from a comprehensive knowledge base, updated and supplemented with articles reviewed by scientific committees.

Read the article

AUTHOR

  • Catherine ETCHEBEST: University Professor - INSERM team leader DSIMB team, UMR-S1134, Université Paris-Diderot, INSERM, INTS, Labex GR-Ex. Paris, France

 INTRODUCTION

Bioinformatics is known as the discipline of exploiting, interpreting and annotating biological data using algorithms, i.e. computational methods. The data most frequently exploited are those relating to genome and protein sequences. However, while knowledge of this information is a prerequisite for characterizing a biological macromolecule, it is not sufficient to understand its function. The latter depends on the appropriate spatial arrangement of the constituent units of these biological macromolecules, such as nucleotides and amino acids. Knowing and analyzing the 3D structure of macromolecules is therefore a necessary step towards a better understanding of their function, and therefore their possible dysfunctions. Various biophysical techniques provide access to this structural information. Circular dichroism, for example, can provide information on the structure of the polypeptide skeleton of proteins, or on the shapes adopted by DNA sequences. Crystallography coupled with X-ray diffraction and nuclear magnetic resonance can provide information on structure on an atomic scale. Exploiting these data, designed to shed light on the characteristic properties of macromolecules, requires the use of computational methods known as "structural bioinformatics" or "molecular modeling".

By analyzing the information available on the 3D structures of proteins, it has been possible to demonstrate close relationships between sequence and structure, in particular the conservation of 3D structure for similar sequences, but also for very different sequences, especially those derived from a common ancestor (homologous sequences). This property can thus be used to predict the 3D structure of a macromolecule from its sequence. This is a major challenge for the projects that have followed on from the massive sequencing projects. These include initiatives to set up and automate procedures for obtaining the 3D structure of proteins. (Protein Structure Initiative) . Similarly, the impact of mutations at distant positions along the sequence can be better understood, as the 3D structure can spatially group these positions. Knowing the structure also enables us to better understand the fine interactions at play between partners, which depend on their relative positions. This makes it possible to understand and improve ligand specificity, and even to potentially design new proteins. (protein design) or new drugs, a major challenge for the coming decades.

Finally, a biological macromolecule is not a rigid object, but rather one capable of adapting to different environments and different partners in order to accomplish its function. This adaptation, which takes place over time, can induce relatively limited or, on the...

You do not have access to this resource.

Exclusive to subscribers. 97% yet to be discovered!

You do not have access to this resource.
Click here to request your free trial access!

Already subscribed? Log in!


The Ultimate Scientific and Technical Reference

A Comprehensive Knowledge Base, with over 1,200 authors and 100 scientific advisors
+ More than 10,000 articles and 1,000 how-to sheets, over 800 new or updated articles every year
From design to prototyping, right through to industrialization, the reference for securing the development of your industrial projects

KEYWORDS

bioinformatics   |   biology   |   Biological Macromolecules   |   3D structures   |   Prediction Methods


This article is included in

Bioprocesses and bioproductions

This offer includes:

Knowledge Base

Updated and enriched with articles validated by our scientific committees

Services

A set of exclusive tools to complement the resources

Practical Path

Operational and didactic, to guarantee the acquisition of transversal skills

Doc & Quiz

Interactive articles with quizzes, for constructive reading

Subscribe now!

Ongoing reading
Structural bioinformatics