Functional plant genomics

The openings offered by functional genomics reconciles organism biology and molecular biology, in order to define an integrative biology that should allow new insights about how a phenotype is built up from a genotype in interaction with its environment. This book covers a wide area of concepts and methods in genomics. This range from international genome sequencing projects to invaluable bioinformatics tools, analytical methods of gene expression, including final metabolic products, and their specific tissue to cellular compartmentalization. This new knowledge enables readers to understand the integration of basic physiological functions, and developmental programs. Also, the establishment of tight relationships between genomics, and genetics and plant breeding reveals synergies for exploiting molecular markers, for analysing genetic variation, or for studying quantitative traits. The integration that is now feasible by these new approaches also effects ecophysiology, and opens up new perspectives for the us

• Structural Genomics and in silico Analysis: Physical Structure of the Plant Nuclear Genome
• The Sequencing of Plant Nuclear Genomes
• Introduction to Bioinformatics
• Databases in Biology
• Gene Prediction
• Detecting Protein Function from Genome Sequences
• Large-scale Protein Sequence Comparisons Functional Genomics: From Sequence to Function in Plants: Gene Transfer to Plants
• Mutant Libraries: A High-throughput Arabidopsis Reverse Genetics System
• DNA Microarrays in Plants
• Statistical Design and the Analysis of Gene Expression Determined by Independent Component Analysis
• Proteomics
• Tracking Gene Expression in Plant Cells: Microscopy and Associated Bio-imaging Techniques
• Tracking Gene Expression in Plant Cells: New Probes for Functional Genomics
• Metabolomics
• Metabolic Fingerprinting and Profiling by Proton NMR
• Methods for the Qualitative and Quantitative Analysis of Metabolic Fluxes
• The Structure of Metabolic Networks or (almost) All that is Known about the Simplest Metabolic Network Plant Models in Genomics: The Model Species, Arabidopsis thaliana
• Rice, a Model Plant for Cereal Genomics
• The Model Medicago truncatula: From Plant-Microbe Symbioses to Crop Legume Breeding Boosted by Cross-Legume Genomics
• Tomato: A Model Plant for Solanaceae Genomics
• Genomics as a Road for Grapevine Improvement
• Sugarcane, a Tropical Crop with a Highly Complex Genome Genomics, Genetic Variability and Plants Breeding: Molecular Markers and High-throughput Genotype Analysis
• Transposable Elements and the Analysis of Plant Biodiversity
• Analysis of Complex Characters into Elementary Components the Use of Molecular Quantitative Genetics in Arabidopsis thaliana
• Characterisation of Major Genes and QTLs by a Candidate Gene Approach
• Molecular Evolution and Validation of Candidate Gene
• Genomics and Plant Breeding: Maize and Wheat Genomics, Agronomy, Technology and Patenting: From Genomics to Self-assemblyMetabolic Fingerprinting and Profiling by MID-FT-IR (Middle-Fourier Transforme