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Full Description
The global population is projected to reach almost 10 billion by 2050, and food and feed production will need to increase by 70%. Wheat, maize and sorghum are three key cereals which provide nutrition for the majority of the world's population. Their production is affected by various abiotic stresses which cause significant yield losses. The effects of climate change also increase the frequency and severity of such abiotic stresses. Molecular breeding technologies offer real hope for improving crop yields. Although significant progress has been made over the last few years, there is still a need to bridge the large gap between yields in the most favorable and most stressful conditions. This book: - Provides a valuable resource for wheat, maize and sorghum scientists working on breeding and molecular biology, physiology and biotechnology. - Presents the latest in-depth research in the area of abiotic stress tolerance and yield improvements. - Contains the necessary information to allow plant breeders to apply this research to effectively breed new varieties of these crops. It provides a consolidated reference for plant breeders and crop scientists working on the challenges of enhanced crop productivity and climate change adaptability.
Contents
Chapter 1: Recent Understanding on Molecular Mechanisms of Plant Abiotic Stress Response and Tolerance Chapter 2: Breeding Strategies to Enhance Abiotic Stress Tolerance and Yield Improvement in Wheat, Maize and Sorghum Chapter 3: Recent Advancement of Molecular Breeding for Improving Salinity Tolerance in Wheat Chapter 4: Genomics and Molecular Physiology for Improvement of Drought Tolerance in Wheat Chapter 5: Molecular Breeding for Improving Heat Stress Tolerance in Wheat Chapter 6: Molecular Breeding for Improving Waterlogging Tolerance in Wheat Chapter 7: Molecular Breeding for Improving Aluminium Resistance in Wheat Chapter 8: Molecular Breeding for Enhancing Iron and Zinc Content in Wheat Grains Chapter 9: Recent Advancements of Molecular Breeding and Functional Genomics for Improving Nitrogen-, Phosphorus- and Potassium-Use Efficiencies in Wheat Chapter 10: Molecular Breeding for Improving Yield in Wheat: Recent Advances and Future Perspectives Chapter 11: Tools for Transforming Wheat Breeding: Genomic Selection, Rapid Generation Advance and Database-Based Decision Support Chapter 12: CRISPR-Mediated Gene Editing in Wheat for Abiotic Stress Tolerance Chapter 13: Application of Pangenomics for Wheat Molecular Breeding Chapter 14: Recent Advancement of Molecular Understanding for Combating Salinity Stress in Maize Chapter 15: Isolation of Genes/Quantitative Trait Loci for Drought Stress Tolerance in Maize Chapter 16: The Genetic Architecture and Breeding Towards Cold Tolerance in Maize: Review Chapter 17: Physiological and Molecular Mechanisms Underlying Excess Moisture Stress Tolerance in Maize: Molecular Breeding Opportunities to Increase Yield Potential Chapter 18: Recent Molecular Breeding Advances for Improving Aluminium Tolerance in Maize and Sorghum Chapter 19: Physiological and Molecular Interventions for Improving Nitrogen-Use Efficiency in Maize Chapter 20: Recent Advancement in Molecular Breeding for Improving Nutrient-Use Efficiency in Maize Chapter 21: Molecular Breeding for Increasing Nutrition Quality in Maize: Recent Progress Chapter 22: Molecular Breeding for Improving Yield in Maize: Recent Advances and Future Perspectives Chapter 23: CRISPR-Mediated Genome Editing in Maize for Improved Abiotic Stress Tolerance Chapter 24: Molecular Breeding for Combating Salinity Stress in Sorghum: Progress and Prospects Chapter 25: Quantitative Trait Locus mapping and Genetic Improvement to Strengthen Drought Tolerance in Sorghum Chapter 26: Improving Abiotic Stress Tolerance to Adapt Sorghum to Temperate Climatic Regions Chapter 27: Isolation of Quantitative Trait Loci/Gene(s) Conferring Cadmium Tolerance in Sorghum Chapter 28: Molecular Breeding for Increasing Micronutrient Content in Sorghum Chapter 29: Ideotype Breeding for Improving Yield in Sorghum: Recent Advances and Future Perspectives
