Physiology and biotechnology integration for plant breeding

Global demand for wheat, rice, corn, and other essential grains is expected to steadily rise over the next twenty years. Meeting this demand by increasing production through increased land use is not very likely; and while better crop management may make a marginal difference, most agriculture experts agree that this anticipated deficit must be made up through increased crop yields. The first resource of its kind, Physiology and Biotechnology Integration for Plant Breeding assembles current research in crop plant physiology, plant biotechnology, and plant breeding that is aimed toward improving crop plants genetically while supporting a productive agriculture ecosystem. Highly comprehensive, this reference provides access to the most innovative perspectives in crop physiology - with a special emphasis on molecular approaches - aimed at the formulation of those crop cultivars that offer the greatest potential to increase crop yields in stress environments. Surveys the current state of the field, as well as modern options and avenues for plant breeders and biotechnologists interested in augmenting crop yield and stability With the contributions of plant scientists from all corners of the globe who are actively involved in meeting this important challenge, Physiology and Biotechnology Integration for Plant Breeding provides readers with the background information needed to understand this cutting-edge work, as well as detailed information on present and potential applications. While the first half of the book establishes and fully explains the link between crop physiology and molecular biology, the second part explores the application of biotechnology in the effective delivery of the high yield and environmentally stable crop plants needed to avert the very real possibility of worldwide hunger.

PHYSIOLOGICAL BASIS OF YIELD AND ENVIRONMENTAL ADAPTATION. Physiology of Yield and Adaptation in Wheat and Barley Breeding. Genetic Yield Improvement and Stress Tolerance in Maize. Physiological Basis of Yield and Environmental Adaptation in Rice. Sorghum Physiology. Pearl Millet. Comparative Ecophysiology of Cowpea, Common Bean, and Peanut. The Physiological Basis of Soybean Yield Potential and Environmental Adaptation. The Physiological Basis of Yield and Environmental Adaptation. APPLICATION OF BIOTECHNOLOGY TO IMPROVE CROP YIELD AND ADAPTATION. Genome Mapping and Genomic Strategies for Crop Improvement. Marker-Assisted Utilization of Exotic Germplasm. Heterosis of Yield: Molecular and Biochemical Perspectives. Genetic Engineering for Enhancing Plant Productivity and Stress Tolerance. Genome Mapping and Marker-Assisted Selection for Improving Cotton (Gossypium spp.) Productivity and Quality in Arid Regions. Molecular Dissection of Abiotic Stress Tolerance in Sorghum and Rice. Genetic Dissection of Drought Resistance in Maize: A Case Study. Physiology and Biotechnology Integration for Plant Breeding: Epilogue.