Genomics and Post-Genomics
E-Book, Englisch, 252 Seiten, E-Book
ISBN: 978-0-470-02002-9
Verlag: John Wiley & Sons
Format: PDF
Kopierschutz: Adobe DRM (»Systemvoraussetzungen)
After a brief introduction to gene structure and sequencedetermination, it describes the techniques used to identify genes,their protein-coding sequences and regulatory regions. The bookdiscusses the methodology of comparative genomics, usinginformation from different organisms to deduce information aboutunknown sequences. There is a comprehensive chapter on structureprediction, covering both RNA and protein. Finally, the bookdescribes the complex networks of RNA and protein that exist withinthe cell and their interactions, ending with a discussion of thesimulation approaches that can be used to model these networks.
Praise from the reviews:
"In context of the new developments the genomic era hasbrought, Bioinformatics: Genomics and Post-Genomics becomes afundamental and indispensable resource for undergraduate and earlygraduate students...insightfully authored...will immenselyhelp students...in establishing important foundations whileshaping their careers." NEWSLETTER, BRITISH SOCIETY OFCELL BIOLOGY
Weitere Infos & Material
Chapter 1. Genome sequencing.
1.1 Automatic sequencing.
1.2 Sequencing strategies.
1.3 Fragmentation strategies.
1.4 Sequence assembly.
1.5 Filling gaps.
1.6 Obstacles to reconstruction.
1.7 Utilizing a complementary 'large' clonelibrary.
1.8 The first large-scale sequencing project: The Haemophilusinfluenzae genome.
1.9 cDNA and EST.
Chapter 2. Sequence comparisons.
2.1 Introduction: Comparison as a sequence predictionmethod.
2.2 A sample molecule: the human and rosterone receptor.
2.3 Sequence homologies - functional homologies.
2.4 Comparison matrices.
2.5 The problem of insertions and deletions.
2.6 Optimal alignment: the dynamic programming method.
2.7 Fast heuristic methods.
2.8 Sensitivity, specificity, and confidence level.
2.9 Multiple alignments.
Chapter 3. Comparative genomics.
3.1 General properties of genomes.
3.2 Genome comparisons.
3.3 Gene evolution and phylogeny: applications toannotation.
Chapter 4. Genetic information and biological sequences.
4.1 Introduction: Coding levels.
4.2 Genes and the genetic code.
4.3 Expression signals.
4.4 Specific sites.
4.5 Sites located on DNA.
4.6 Sites present on RNA.
4.7 Pattern detection methods.
Chapter 5. Statistics and sequences.
5.1 Introduction.
5.2 Nucleotide base and amino acid distribution.
5.3 The biological basis of codon bias.
5.4 Using statistical bias for prediction.
5.5 Modeling DNA sequences.
5.6 Complex models.
5.7 Sequencing errors and hidden Markov models.
5.8 Hidden Markov processes: a general sequence analysistool.
5.9 The search for genes - a difficult art.
Chapter 6. Structure prediction.
6.1 The structure of RNA.
6.2 Properties of the RNA molecule.
6.3 Secondary RNA structures.
6.4 Thermodynamic stability of RNA structures.
6.5 Finding the most stable structure.
6.6 Validation of predicted secondary structures.
6.7 Using chemical and enzymatic probing to analyze folding.
6.8 Long-distance interactions and three-dimensional structureprediction.
6.9 Protein structure.
6.10 Secondary structure prediction.
6.11 Three-dimensional modeling based on homologous proteinstructure.
6.12 Predicting folding.
Chapter 7. Transcriptome and proteome: macromolecularnetworks.
7.1 Introduction.
7.2 Post-genomic methods.
7.3 Macromolecular networks.
7.4 Topology of macromolecular networks.
7.5 Modularity and dynamics of macromolecular networks.
7.6 Inference of regulatory networks.
Chapter 8. Simulation of Biological Processes in the GenomeContext.
8.1 Types of simulations.
8.2 Prediction and explanation.
8.3 Simulation of molecular networks.
8.4 Generic post-genomic simulators.
Index.
