This book is dedicated to the multiple aspects, that is, biological, physical and computational of DNA and RNA molecules. These molecules, central to vital processes, have been experimentally studied by molecular biologists for five decades since the discovery of the structure of DNA by Watson and Crick in 1953. Recent progresses (e.g. use of DNA chips, manipulations at the single molecule level, availability of huge genomic databases...) have revealed an imperious need for theoretical modelling. Further progresses will clearly not be possible without an integrated understanding of all DNA and RNA aspects and studies. The book is intended to be a desktop reference for advanced graduate students or young researchers willing to acquire a broad interdisciplinary understanding of the multiple aspects of DNA and RNA. It is divided in three main sections: The first section comprises an introduction to biochemistry and biology of nucleic acids. The structure and function of DNA are reviewed in R. Lavery's chapter. The next contribution, by V. Fritsch and E. Westhof, concentrates on the folding properties of RNA molecules.
The cellular processes involving these molecules are reviewed by J. Kadonaga, with special emphasis on the regulation of transcription. These chapters does not require any preliminary knowledge in the field (except that of elementary biology and chemistry). The second section covers the biophysics of DNA and RNA, starting with basics in polymer physics in the contribution by R. Khokhlov. A large space is then devoted to the presentation of recent experimental and theoretical progresses in the field of single molecule studies. T. Strick's contribution presents a detailed description of the various micro-manipulation techniques, and reviews recent experiments on the interactions between DNA and proteins (helicases, topoisomerases, ...). The theoretical modeling of single molecules is presented by J. Marko, with a special attention paid to the elastic and topological properties of DNA. Finally, advances in the understanding of electrophoresis, a technique of crucial importance in everyday molecular biology, are exposed in T. Duke's contribution.
The third section presents provides an overview of the main computational approaches to integrate, analyse and simulate molecular and genetic networks. First, J. van Helden introduces a series of statistical and computational methods allowing the identification of short nucleic fragments putatively involved in the regulation of gene expression from sets of promoter sequences controlling co-expressed genes. Next, the chapter by Samsonova et al. connects this issue of transcriptional regulation with that of the control of cell differentiation and pattern formation during embryonic development. Finally, H. de Jong and D. Thieffry review a series of mathematical approaches to model the dynamical behaviour of complex genetic regulatory networks. This contribution includes brief descriptions and references to successful applications of these approaches, including the work of B. Novak, on the dynamical modelling of cell cycle in different model organisms, from yeast to mammals.
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(229mm x 152mm x 20mm)
Elsevier Science Ltd
Publisher: Elsevier Science & Technology
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Author Biography - Didier Chatenay
Didier Chatenay activities since 1995 is devoted to experimental research at the frontiers between physics and biology. His first contributions were in the field of single molecule experiments and particulary in the micromanipulation of single nucleic acid molecules (DNA, RNA). In particular he evidenced new structural transitions of a single DNA molecule submitted to an external force. Simona Cocco's research activity since 2001 is devoted to the applications of statistical physics to biophysics. Her main contributions on the latter issue, in collaboration with Remi Monasson, are related to the modeling of single molecule experiments, in particular the structural transtitions of the DNA and RNA molecules under mechanical stress. Remi Monasson's research activity since 1995 is devoted to the applications of statistical physics to interdisciplinary fields as computer science and biophysics. His main contributions on the latter issue, in collaboration with Simona Cocco, are related to the modeling of single molecule experiments, in particular the structural transitions of the DNA and RNA molecules under mechanical stress. The research of Denis Thieffry focuses on the development of qualitative tools for the integration, the modeling and the dynamical analysis of biological regulatory networks. These tools are currently applied to the dynamical modeling of gene networks involved in development, cell cycle and cancer. Jean Dalibard works in the field of atomic physics and quantum optics. His recent activities is centered on the physics of cold quantum gases, in particular Bose-Einstein condensation.