Hoboken, New Jersey : , : Wiley Blackwell, , [2021]

©2021

1-119-63316-8

1-119-63317-6

1-119-63315-X

1 online resource (467 pages)

633.18

Rice - Effect of stress on - Genetic aspects

Inglese

Cover -- Title Page -- Copyright -- Contents -- Editor Biographies -- Preface -- List of Contributors -- Chapter 1 Rice Adaptation to Climate Change: Opportunities and Priorities in Molecular Breeding -- Introduction -- Rice Production Scenario and Climate Change -- Prospects of Molecular Breeding for Climate‐Resilient Rice -- Molecular Breeding in Rice -- Breeding for Abiotic Stress Tolerance -- Drought -- Salinity -- Submergence -- High Temperature -- Low Temperature -- Breeding for Biotic Stress Tolerance -- Diseases -- Pests -- Weed Competitiveness -- Conclusion -- References -- Chapter 2 Molecular Breeding for Improving Salinity Tolerance in Rice: Recent Progress and Future Prospects -- Introduction -- Salt Tolerance Mechanisms -- Root‐Level Ion Exclusion -- Plant‐Level Compartmentation -- Cell‐Level Compartmentation -- Natural Variability for Salt Tolerance in Rice Germplasm -- Conventional Tools to Improve Salinity Tolerance -- Conventional Breeding -- Mutation Breeding -- Tissue Culture -- Molecular Tools to Improve Salinity Tolerance -- QTL Mapping -- Marker‐Assisted Selection -- Candidate Genes and Allele Mining -- Genetic Engineering to Improve Salt Tolerance -- Novel Tools to Aid in Molecular Breeding -- Multi‐Parental Advanced Generation Intercross Strategy -- Genomic Selection -- Phenomics -- Next‐Generation Sequencing -- Genome Editing -- Conclusion and Future prospects --

Acknowledgments -- References -- Chapter 3 Molecular Breeding for Improving Drought Tolerance in Rice: Recent Progress and Future Perspectives -- Introduction -- The Drought Challenges and Its Distribution -- Climate Change and Drought -- Drought Impacts on the Rice Plant -- Drought Phenotyping Platforms -- Drought Screening Protocols -- Field‐Based Phenotyping -- Design and Management of Field Drought Experiments -- Trait‐Based Selection for Drought Resistance.

Direct Selection for Yield Under Stress -- Molecular Markers and Genotyping Strategies -- Genome‐Wide Scans with Microsatellite Markers (Simple Sequence Repeats, SSRs) -- SNP (Single Nucleotide Polymorphism) Genotyping -- Trait‐Specific SNPs Used as Diagnostic Markers -- Genetic Basis of Drought Tolerance in Rice -- Mapping and Deployment of Drought QTLs -- Fine Mapping of Identified Genetic Regions -- Development of NILs and PLs Carrying Drought QTLs in Background of High Yielding Rice Varieties -- MAS Introgression of Multiple Traits -- Understanding the Molecular Basis of Complexities of Epistatic Interactions -- Modern Breeding Strategies and Programs for Accelerated Genetic Gain -- Rapid Breeding Cycles -- Novel Breeding Strategies Using GS -- Deployment of Genome Editing, Especially the CRISPR Technologies -- Conclusion -- References -- Chapter 4 Molecular Breeding for Improving Flooding Tolerance in Rice: Recent Progress and Future Perspectives -- Introduction -- Rice Tolerant to Germination Stage Oxygen Deficiency and Submergence and Stagnant Flooding? -- History of Flooding Tolerance and Molecular Breeding -- Convergence of Conventional and Molecular Breeding -- Conclusion and Future Perspective -- Acknowledgment -- References -- Chapter 5 Molecular Breeding for Improving Heat Stress Tolerance in Rice: Recent Progress and Future Perspectives -- Introduction -- Climate Change and Heat Tolerance Genotype Needs -- Recent Progress on Rice Breeding -- Plant Physiology on Heat‐Stress Response -- Net Photosynthesis Rate -- Grain Filling -- Response in Germination -- Response in Anthesis -- Amylose Content Response to Heat -- Heat‐Induced Quality Decline of Rice (White‐Back Kernel) -- Source Sink Dynamics -- Genetic Background -- Breeding Materials (Donors) -- Genetic Diversity Analysis -- Phenotyping -- Putative and Candidate Genes/QTLs.

Marker‐Assisted Selection (Microsatellites and SNP Arrays) -- Proteomics -- Future Perspectives -- Conclusions -- References -- Chapter 6 Molecular Breeding for Improving Cold Tolerance in Rice: Recent Progress and Future Perspectives -- Introduction -- Preliminary Mapping of Cold‐Tolerant QTLs and Fine Mapping of Major Loci -- Map‐Based Cloning and Molecular Mechanism of Cold‐Resistant QTLs -- Molecular Regulatory Networks for Cold Tolerance in Oryza sativa -- CBF Regulatory Pathway -- MYB Regulatory Pathway -- Outlook -- References -- Chapter 7 Molecular Breeding for Lower Cadmium Accumulation in Rice Grain: Progress and Perspectives -- Introduction -- Cd Toxicity to Human Health -- The Origin of Cd Contamination in Soils -- Cd Accumulation in Rice -- Cd Uptake and Distribution Patterns During the Whole Growth Cycle of Rice -- The Diversity of Cd Accumulation Trait in Different Varieties of Rice -- Genetic Basis for Cd Accumulation in Rice -- Influence of Environmental Factors on Cd Accumulation in Rice -- Influence of Soil Water on Rice Cd Accumulation -- Influence of pH Values in Soil and Irrigation Water on Rice Cd Accumulation -- Effect of the Application of Other Ions or Chemical Compounds on Rice Cd Accumulation -- Influence of Rhizosphere Microorganisms on Rice Cd Accumulation -- Influence of Genetic Factors on Cd Accumulation in Rice -- Transporters for Cd

Uptake and Translocation -- Genes Involved in Cd Chelation -- Regulating Genes to Mediate Grain Cd Accumulation in Rice -- Molecular Breeding for Low‐Cd Accumulation in Rice Grains -- Screening and Identification of Low‐Cd Varieties -- Molecular Marker‐Assisted Low‐Cd Gene Aggregation Breeding -- Gene Editing‐Based Molecular Breeding -- Conclusions and Perspectives -- Acknowledgments -- References.

Chapter 8 Molecular Breeding for Improving Arsenic Stress Tolerance in Rice: Recent Progress and Future Perspectives -- Introduction -- Tolerance to Arsenic in Rice -- The Phytotoxic Effects of Arsenic and the Rice Defense Response -- Genetic Diversity for Arsenic Tolerance -- Genetic Bases of Arsenic Tolerance -- Molecular Breeding Options for Rice Tolerance to Arsenic -- Marker‐Assisted Recurrent Selection -- Genomic Selection -- Genomic Selection for Arsenic Tolerance in Rice: A Case Study -- Methods -- Genomic Prediction Results -- Cross‐Validation Within the Reference Population -- Genomic Prediction Across Populations -- Implication for Breeding for Arsenic Tolerance -- Future Prospects -- References -- Chapter 9 Molecular Breeding for Improving Ozone Tolerance in Rice: Recent Progress and Future Perspectives -- Introduction -- Tropospheric Ozone: A Major Threat to Rice Production in Asia -- Mechanisms of Ozone Damage -- Ozone Tolerance Mechanisms -- Ozone‐Impact Assessments -- Molecular Breeding Strategies for Improved Ozone Tolerance -- Breeding Progress and Future Perspectives of Ozone Tolerance in Rice -- Conclusion -- References -- Chapter 10 Molecular Breeding Strategies for Enhancing Rice Yields Under Low Light Intensity -- Introduction -- Effect of Low Light in Rice Physiology, Development and Yield -- Candidate Genes and Pathways Imparting Tolerance -- Low Light Perception -- Molecular Targets for Erect Lamina -- Molecular Basis of Delayed Senescence -- Cross Talk Between Various Stresses -- "Omics" and Mapping Studies -- Future Prospects and Molecular Breeding Strategy -- References -- Chapter 11 Harnessing Tolerance to Low Phosphorus in Rice: Recent Progress and Future Perspectives -- Introduction -- Phosphorus Uptake and Assimilation in Plants -- Role of Low P in Rice Development and Growth -- Uptake and Transport of P in Rice.

Signaling in Response to Low Pi -- Assimilation of P in Rice -- Vegetative Stage -- Reproductive Stage -- Impact of P Deficiency on Rice -- Resources That Have Helped Enhance the Understanding of Low P Tolerance in Rice -- QTLs -- Functionally Validated Low P Tolerance Potential Candidates -- Molecular Targets Available in Rice for Breeding -- PUP1 History and Deployment of PUP1 Based Markers for MAS -- Other Haplotypes Reported for PUP1 and Implications for Breeding Program -- Beyond PSTOL1 -- Future Prospects -- Acknowledgments -- References -- Chapter 12 Molecular Breeding for Improving Nitrogen Use Efficiency in Rice: Progress and Perspectives -- Introduction -- Evaluation of Genetic Variation for Nitrogen Use Efficiency -- Identification of QTL and Genomic Regions through Biparental and Association Mapping -- QTL -- Association Mapping -- Expression Analyses of Candidate Genes Associated with Nitrogen Metabolism -- Ways to Go for the Development of Rice Varieties -- Conclusions -- References -- Chapter 13 Dissecting the Molecular Basis of Drought‐Induced Oxidative Stress Tolerance in Rice -- Introduction -- Effect of Drought Stress in Rice -- Sources of ROS Production during Drought Stress in Rice Plants -- Antioxidative Defenses and Redox Homeostatic Mechanisms in Rice in Response to Drought -- ROS Signaling under Drought Stress -- High‐Throughput Technologies to Identify Drought‐Induced Oxidative Stress‐Tolerance

Mechanisms -- Genome Editing Using CRISPR‐Cas9 Technology -- Expressed Sequence Tags (ESTs) -- Gene Networks -- RNA‐Seq Technology -- Micro‐RNA (miRNA) Technology -- Virus‐Induced Gene‐Silencing Machinery -- TILLING (Targeting Induced Local Lesions in Genomes) -- Identification of Superior Alleles or QTLs Associated with Drought Tolerance -- Molecular Mechanism in Tolerant Genotype in Comparison to Sensitive Genotype under Drought.

Conclusion and Future Perspectives.

"The chapters of this book aim to contribute the latest understandings of molecular and genetic bases of abiotic stress tolerance, yield and quality improvement of rice to develop strategies for abiotic stress tolerance and biofortification, which leads to enhanced crop productivity under abiotic stress conditions, as well as better utilization of natural resources to ensure food security through modern breeding. Topics covered include: - Rice adaptation to climate change - Molecular breeding for improving UB-radiation tolerance in rice - Molecular breeding for improving abiotic oxidative stress tolerance in rice - Molecular breeding for grain quality improvement in rice - Application of rapid generation advance system in rice breeding for the development of stress tolerant rice varieties This book will provide comprehensive information on each topic, much needed by scientists and plant breeders for developing new stress tolerant rice varieties"--