Evolution after Gene Duplication
Editat de Katharina Dittmar, David Liberlesen Limba Engleză Hardback – 17 sep 2010
- Explores comparative genomics, genome evolution studies and analysis of multi–gene families such as Hox, globins, olfactory receptors and MHC (immune system)
- A complete post–genome treatment of the topic originally covered by Ohno′s 1970 classic, this volume extends coverage to include the fate of associated regulatory pathways
- Taps the significant increase in multi–gene family data that has resulted from comparative genomics
- Comprehensive coverage that includes opposing theoretical viewpoints, comparative genomics data, theoretical and empirical evidence and the role of bioinformatics in the study of gene duplication
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Specificații
ISBN-13: 9780470593820
ISBN-10: 0470593822
Pagini: 360
Ilustrații: Illustrations
Dimensiuni: 184 x 7 x 22 mm
Greutate: 0.8 kg
Editura: Wiley
Locul publicării:Hoboken, United States
ISBN-10: 0470593822
Pagini: 360
Ilustrații: Illustrations
Dimensiuni: 184 x 7 x 22 mm
Greutate: 0.8 kg
Editura: Wiley
Locul publicării:Hoboken, United States
Public țintă
Bioinformatics, biochemistry, biophysics, molecular biology, phylogenetics, molecular evolution, medicine, biotechnology, evolutionary biology/genetics, systems biologists Instructors, grad students, advanced undergrad students, academic professionalsDescriere
The first book to examine gene duplication across all levels of biological organization The duplication of genes and genomes has long been postulated to have played a major role in the rise of biological novelty through evolution of new function and gene expression patterns. This biological novelty is represented on multiple levels, ranging from new genes, proteins, network interactions, and expression patterns to new species. Evolution after Gene Duplication is the first venue in which gene duplication is examined across all levels of biological organization in order to present a comprehensive picture of the mechanistic process by which gene duplication may have played a part in generating biodiversity.
Bringing together experts from various disciplines, the book:
Evolution after Gene Duplication is suitable for scientists across various levels of biology as well as instructors and graduate students. It is pertinent to anyone involved in comparative genomics, genome evolution studies, or analysis of any of the multi–gene families.
Bringing together experts from various disciplines, the book:
- Links the evolutionary process associated with gene duplication through structure to function
- Describes the link between the process of gene duplication and protein structure
- Presents a procedure for linking changes in gene copy number through evolution to functional and gene expression evolution
- Offers an overview of model and parsimony–based approaches for gene tree/species tree reconciliation
- Explains the energetic costs of gene duplication, the interplay between systems–level constraints and duplicate gene retention, and the complementary interplay between duplication and the structure of biological networks
- Explores comparative genomics, genome evolution studies, and analysis of multi–gene families such as Hox, globins, olfactory receptors, and MHC (immune system)
- Taps the significant increase in multi–gene family data that has resulted from comparative genomics
- Features opposing theoretical viewpoints, comparative genomics data, theoretical and empirical evidence, and the role of bioinformatics in the study of gene duplication
- Includes the fate of associated regulatory pathways
Evolution after Gene Duplication is suitable for scientists across various levels of biology as well as instructors and graduate students. It is pertinent to anyone involved in comparative genomics, genome evolution studies, or analysis of any of the multi–gene families.
Textul de pe ultima copertă
The first book to examine gene duplication across all levels of biological organization The duplication of genes and genomes has long been postulated to have played a major role in the rise of biological novelty through evolution of new function and gene expression patterns. This biological novelty is represented on multiple levels, ranging from new genes, proteins, network interactions, and expression patterns to new species. Evolution after Gene Duplication is the first venue in which gene duplication is examined across all levels of biological organization in order to present a comprehensive picture of the mechanistic process by which gene duplication may have played a part in generating biodiversity.
Bringing together experts from various disciplines, the book:
Evolution after Gene Duplication is suitable for scientists across various levels of biology as well as instructors and graduate students. It is pertinent to anyone involved in comparative genomics, genome evolution studies, or analysis of any of the multi–gene families.
Bringing together experts from various disciplines, the book:
- Links the evolutionary process associated with gene duplication through structure to function
- Describes the link between the process of gene duplication and protein structure
- Presents a procedure for linking changes in gene copy number through evolution to functional and gene expression evolution
- Offers an overview of model and parsimony–based approaches for gene tree/species tree reconciliation
- Explains the energetic costs of gene duplication, the interplay between systems–level constraints and duplicate gene retention, and the complementary interplay between duplication and the structure of biological networks
- Explores comparative genomics, genome evolution studies, and analysis of multi–gene families such as Hox, globins, olfactory receptors, and MHC (immune system)
- Taps the significant increase in multi–gene family data that has resulted from comparative genomics
- Features opposing theoretical viewpoints, comparative genomics data, theoretical and empirical evidence, and the role of bioinformatics in the study of gene duplication
- Includes the fate of associated regulatory pathways
Evolution after Gene Duplication is suitable for scientists across various levels of biology as well as instructors and graduate students. It is pertinent to anyone involved in comparative genomics, genome evolution studies, or analysis of any of the multi–gene families.
Cuprins
Contributors. Preface
1 Understanding Gene Duplication through Biochemistry and Population Genetics (David A. Leberles, Grigory Kolesov, and Katharina Dittmar).
2 Functional Divergence of Duplicated Genes (Takashi Makino, David G. Knowles, and Aoife McLysaght).
3 Duplication Retention After Small– and Large–Scale Duplications (Steven Maere and Yves Van de Peer).
4 Gene Dosage and Duplication (Fyodor A. Kondrashov).
5 Myths and Realities of Gene Duplication (Austin L. Hughes and Robert Friedman).
6 Evolution After and Before Gene Duplication? (Tobias Sikosek and Erich Bornberg–Bauer).
7 Protein Products of Tandem Gene Duplication: A Structural View (William R. Taylor and Michael I. Sadowski).
8 Statistical Methods for Detecting Functional Divergence of Gene Familiies (Xun Gu).
9 Mapping Gene Gains and Losses Among Metazoan Full Genomes Using an Integrated Phylogenetic Framework (Athanasia C. Tzika, Raphaël Helaers, and Michel C. Milinkovitch).
10 Reconciling Phylogenetic Trees (Oliver Eulenstein, Snehalata Huzurbazar, and David A. Liberles).
11 On the Energy and Material Cost of Gene Duplication (Andreas Wagner).
12 The Fate of a Duplication in a Network Context (Orkun S. Soyer).
13 Evolutionary and Functional Aspects of Genetic Redundancy (Ran Kafri and Tzachi Pilpel).
14 A Phylogenomic Approach to the Evolutionary Dynamics of Gene Duplication in Birds (Gene L. Organ, Matthew D. Rasmussen, Maude W. Baldwin, Manolis Kellis, and Scott V. Edwards).
15 Gene and Genome Duplications in Plants (Pamela S. Soltis, J. Gordon Burleigh, Andre S. Chanderbali, Mi–Jeong Yoo, and Douglas E. Soltis).
16 Whole Genome Duplications and the Radiation of Vertebrates (Shigehiro Kuraku and Axel Meyer).
Index.
1 Understanding Gene Duplication through Biochemistry and Population Genetics (David A. Leberles, Grigory Kolesov, and Katharina Dittmar).
2 Functional Divergence of Duplicated Genes (Takashi Makino, David G. Knowles, and Aoife McLysaght).
3 Duplication Retention After Small– and Large–Scale Duplications (Steven Maere and Yves Van de Peer).
4 Gene Dosage and Duplication (Fyodor A. Kondrashov).
5 Myths and Realities of Gene Duplication (Austin L. Hughes and Robert Friedman).
6 Evolution After and Before Gene Duplication? (Tobias Sikosek and Erich Bornberg–Bauer).
7 Protein Products of Tandem Gene Duplication: A Structural View (William R. Taylor and Michael I. Sadowski).
8 Statistical Methods for Detecting Functional Divergence of Gene Familiies (Xun Gu).
9 Mapping Gene Gains and Losses Among Metazoan Full Genomes Using an Integrated Phylogenetic Framework (Athanasia C. Tzika, Raphaël Helaers, and Michel C. Milinkovitch).
10 Reconciling Phylogenetic Trees (Oliver Eulenstein, Snehalata Huzurbazar, and David A. Liberles).
11 On the Energy and Material Cost of Gene Duplication (Andreas Wagner).
12 The Fate of a Duplication in a Network Context (Orkun S. Soyer).
13 Evolutionary and Functional Aspects of Genetic Redundancy (Ran Kafri and Tzachi Pilpel).
14 A Phylogenomic Approach to the Evolutionary Dynamics of Gene Duplication in Birds (Gene L. Organ, Matthew D. Rasmussen, Maude W. Baldwin, Manolis Kellis, and Scott V. Edwards).
15 Gene and Genome Duplications in Plants (Pamela S. Soltis, J. Gordon Burleigh, Andre S. Chanderbali, Mi–Jeong Yoo, and Douglas E. Soltis).
16 Whole Genome Duplications and the Radiation of Vertebrates (Shigehiro Kuraku and Axel Meyer).
Index.
Recenzii
"This up–to–date overview of theory and mathematical models along with practical examples is suitable for scientists across various levels of biology as well as instructors and graduate students." (Forbes.com, 27 October 2010)
Notă biografică
Katharina Dittmar de la Cruz holds both a Ph.D. in Molecular Parisitology and Entomology and a doctorate in Veterinary Medicine, both from the University of Leipzig, Germany. An expert in phylogenetics, molecular evolution, and bioinformatics, she has recently turned her attention toward examining the implications of evolutionary forces on drug design. Dr. Dittmar is an Assistant Professor at the SUNY University at Buffalo.
David Liberles earned his Ph.D. in Chemistry at the California Institute of Technology working on the biochemsitry of nucleic acids. Subsequently, he has developed significant expertise in bioinformatics, computational biology and functional genomics. His broad experience includes a professorship at the Stockholm Bioinformatics Center and consultancies with Novo Nordisk and other private research and diagnostic companies. Currently he is Vice-Director of the University of Wyoming Bioinformatics Center and Assistant Professor of Molecular Biology.
David Liberles earned his Ph.D. in Chemistry at the California Institute of Technology working on the biochemsitry of nucleic acids. Subsequently, he has developed significant expertise in bioinformatics, computational biology and functional genomics. His broad experience includes a professorship at the Stockholm Bioinformatics Center and consultancies with Novo Nordisk and other private research and diagnostic companies. Currently he is Vice-Director of the University of Wyoming Bioinformatics Center and Assistant Professor of Molecular Biology.