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11135nam a22004573i 4500 |
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20231204023216.0 |
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231204s2021 xx o ||||0 eng d |
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|a 9783030665302
|q (electronic bk.)
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|z 9783030665296
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|a (MiAaPQ)EBC6606585
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|a (Au-PeEL)EBL6606585
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|a (OCoLC)1250475680
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|a S1-972
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|a 633.18233
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|a Ali, Jauhar.
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|a Rice Improvement :
|b Physiological, Molecular Breeding and Genetic Perspectives.
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|a 1st ed.
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|a Cham :
|b Springer International Publishing AG,
|c 2021.
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|c ©2021.
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|a 1 online resource (507 pages)
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|a text
|b txt
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|a computer
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|2 rdamedia
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|a online resource
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|a Intro -- Foreword -- Preface -- Contents -- Advances in Genetics and Breeding of Rice: An Overview -- 1 Introduction -- 2 First Breakthrough: The Green Revolution -- 3 Second Breakthrough: Hybrid Rice Technology -- 4 Next Breakthrough: Strategies -- 4.1 Enrichment of the Rice Gene Pool -- 4.2 Discovery and Stacking of Yield Genes Hidden in Wild/Weedy Species -- 4.3 Designing of Plant Architecture or Ideotype Breeding -- 4.4 Designing of Shoot and Panicle Architecture -- 4.5 Modification of Root Architecture -- 4.6 Green Super Rice for Sustainable Performance -- 4.7 Physiological Breeding Approaches -- 4.8 Defending Against Biophysical Stresses -- 4.9 Selective Modification of Traits by Gene Editing -- 5 Conclusions -- References -- Strategies for Engineering Photosynthesis for Enhanced Plant Biomass Production -- 1 Introduction -- 2 Improving Rubisco Performance -- 2.1 Rubisco Kinetics -- 2.2 Photorespiration Bypass -- 3 Improving Thermotolerance of Rubisco Activase -- 4 Increasing CO2 Concentration Around Rubisco -- 5 Enhancing Activity of Calvin-Benson-Cycle Enzymes -- 6 Enhancing Electron Transport Rate in Thylakoid Membranes -- 7 Improving Photosynthetic Performance Under Fluctuating Light in Natural Environments -- 7.1 Electron Transport -- 7.2 Activation of Calvin-Cycle Enzymes, Especially Rubisco -- 7.3 CO2 Diffusion into the Chloroplast -- 8 Future Prospects -- References -- Green Super Rice (GSR) Traits: Breeding and Genetics for Multiple Biotic and Abiotic Stress Tolerance in Rice -- 1 Introduction -- 2 Green Super Rice -- 2.1 GSR Breeding and Population Development -- 3 Genetics of Green Traits -- 3.1 Drought Tolerance -- 3.2 Salinity Tolerance -- 3.3 Submergence Tolerance -- 3.4 Nutrient-Use Efficiency -- 3.5 Weed-Competitive Ability Traits -- 3.6 Low-Temperature Stress Tolerance at Different Crop Growth Stages -- 3.7 Grain Quality.
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|a 3.8 Biotic Stress Tolerance -- 4 Molecular Genetics and Breeding Strategies to Combine Multiple Stresses -- 4.1 Dissecting the Stress-Regulated Mechanisms for Multiple Stress Tolerance -- 4.2 Breeding Products Combining Tolerance of Multiple Stresses -- 4.3 Development of Rice Hybrids with Multiple-Stress Tolerance -- 5 Conclusions -- References -- Advances in Two-Line Heterosis Breeding in Rice via the Temperature-Sensitive Genetic Male Sterility System -- 1 Introduction -- 2 The Emergence of Two-Line Hybrid Rice Technology with a Historical Perspective -- 3 Advantages and Disadvantages of the TGMS System in the Tropics -- 4 Physiological Characterization of the TGMS Trait -- 4.1 Determination of CSTP and CFTP -- 4.1.1 Characterization Under Controlled-Temperature Screening Conditions -- 4.1.2 Field Screening Through Sequential Seeding -- 4.2 Determination of the Critical Stage for Fertility-Sterility Alteration -- 4.3 Evaluation of TGMS Lines for Sterility-Fertility Alteration in Different Environments -- 4.4 Improvement of Outcrossing Traits in TGMS and Pollen Parental Lines -- 5 Genetics of TGMS Lines -- 5.1 Identification of Genes Governing the TGMS Trait -- 5.2 Molecular Mechanisms of the TGMS Trait -- 6 Breeding of TGMS and Pollen Parental Lines -- 6.1 Different Available Approaches to Breed TGMS Lines -- 6.1.1 Mutation Breeding for the Identification of TGMS Mutants -- 6.1.2 Pedigree Breeding -- 6.1.3 Transfer from a Known TGMS Gene Source to Elite Lines -- 6.1.4 Pyramiding TGMS Genes for Better Stability -- 6.2 Rapid Fixation of Segregating TGMS Lines -- 6.3 Breeding Pollen Parents -- 6.4 Two-Line indica/japonica Hybrids -- 7 Breeding Two-Line Hybrids -- 7.1 Combining Ability Nurseries -- 7.2 Breeding Trials -- 7.3 Insect Pest and Disease Resistance -- 7.4 Grain Quality Considerations Addressing Market Needs -- 8 Seed Production Challenges.
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|a 8.1 Identification of Ideal Locations for Self-Seed Multiplication of TGMS and Hybrid Rice Seed Production -- 9 Wide-Scale Adoption and Use of Two-Line Hybrid Rice Technology -- 10 Future Directions and Conclusions -- References -- Growing Rice with Less Water: Improving Productivity by Decreasing Water Demand -- 1 Introduction -- 2 Current Rice Cultivars/Varieties Grown Under Water-Limiting Conditions -- 3 Existing Rice Cultivation Practices Under Water-Deficit Conditions -- 3.1 Plant-Based Strategies -- 3.1.1 Selection of Cultivars/Varieties -- 3.1.2 Date of Planting -- 3.1.3 Decreased Stand Density -- 3.2 Soil- and Irrigation-Based Strategies -- 3.2.1 Alternate Wetting and Drying -- 3.2.2 Saturated Soil Culture -- 3.2.3 Aerobic Rice Development -- 3.2.4 Decreasing Non-beneficial Water Depletions and Water Outflows -- 3.2.5 System of Rice Intensification -- 3.2.6 Sprinkler Irrigation -- 4 Molecular Breeding for Rice Improvement -- 4.1 QTL Mapping -- 4.2 Marker-Assisted Selection -- 4.3 Marker-Assisted Backcrossing -- 4.4 Marker-Assisted Pyramiding -- 4.5 Marker-Assisted Recurrent Selection -- 4.6 Genomic Selection -- 5 Transgenic Strategies -- 6 Future Prospects -- References -- Crop Establishment in Direct-Seeded Rice: Traits, Physiology, and Genetics -- 1 Introduction -- 2 Climate Change and Water Scarcity -- 3 Rice Establishment Methods -- 3.1 Puddled Transplanted Rice -- 3.2 Direct-Seeded Rice -- 4 Traits, Physiology, Genetics, and Breeding -- 4.1 Anaerobic Germination -- 4.1.1 Physiology and Molecular Mechanisms of AG -- 4.1.2 Genetic Factors Underlying the AG Trait -- 4.2 Seed Longevity -- 4.2.1 Physiology and Molecular Mechanisms Affecting Seed Longevity -- 4.2.2 Genetic Factors Affecting Seed Longevity -- 4.3 Early Seedling Vigor -- 4.3.1 Physiology and Molecular Mechanisms of Early Seedling Vigor.
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|a 4.3.2 Genetic Factors Affecting Early Seedling Vigor -- 4.4 Breeding Rice with Improved Germination -- 5 Conclusions -- References -- Genetics and Breeding of Heat Tolerance in Rice -- 1 Climate Change and Global Warming -- 2 Rice Production and Heat Damage -- 3 Heat Tolerance of Rice -- 4 Heat-Tolerant Rice Genetic Resources -- 5 Physiology of Heat Tolerance in Rice -- 6 Genetics of Heat Tolerance in Rice -- 7 Breeding of Heat Tolerance in Rice -- 8 Future Prospects -- References -- Genetics and Breeding of Low-Temperature Stress Tolerance in Rice -- 1 Introduction -- 2 Phenological, Physiological, and Biochemical Indicators of LTS Tolerance at Different Developmental Stages -- 3 Genes/QTLs Underlying LTS in Rice Detected by Linkage Mapping and GWAS -- 3.1 Germination Stage -- 3.2 Seedling Stage -- 3.3 Booting/Flowering Stage -- 4 Molecular Mechanisms of LTS Tolerance -- 4.1 Signaling Pathways Leading to LTS Tolerance from the Cloned Genes -- 4.2 Genome-Wide Association Studies for LTS Tolerance -- 4.3 Transcriptomics Related to LTS Tolerance -- 4.4 Proteomics Related to LTS Tolerance -- 4.5 Metabolomics Related to LTS Tolerance -- 5 Breeding Approaches for LTS Tolerance in Rice -- 5.1 Improving LTS Tolerance by Conventional Breeding Approaches -- 5.2 Improving LTS Tolerance by Selective Introgression -- 5.3 Improving LTS Tolerance by Genetic Transformation -- 5.4 Improving LTS Tolerance by Genome Editing -- 6 Conclusions and Future Prospects -- References -- Arsenic Stress Responses and Accumulation in Rice -- 1 Introduction -- 2 Heavy Metal Contamination -- 2.1 Heavy Metal Interaction with the Biological System -- 2.2 Chronic Arsenic Exposure and Its Adverse Effects on Human Health -- 3 Arsenic Contamination in Paddy Soil -- 3.1 Arsenic Contamination in Rice -- 3.2 Arsenic Speciation in the Rice Ecosystem.
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|a 3.3 Inorganic Arsenic Interaction with Essential Plant Nutrients -- 4 Arsenic-Induced Toxicity Symptoms During Different Growth Stages of Rice -- 4.1 Germination Stage -- 4.2 Vegetative Growth -- 4.3 Reproductive Growth -- 5 Quantitative Trait Loci Associated with Arsenic Stress Tolerance in Rice -- 6 Arsenic Uptake in Rice -- 6.1 Arsenite Uptake -- 6.2 Arsenate Uptake -- 7 Arsenic Translocation in Rice -- 7.1 Arsenite Translocation -- 7.2 Arsenate Translocation -- 8 Arsenic Detoxification and Stress Responses in Rice -- 8.1 The Oxidative Stress Response in Rice -- 8.2 Root Plaque Formation as a Scavenger for Arsenic Stress -- 9 State of Knowledge Gaps for Arsenic Accumulation in Rice -- 10 Possible Mitigation Strategies for Arsenic Accumulation in Rice -- 11 Future Directions and Conclusions -- References -- Molecular Approaches for Disease Resistance in Rice -- 1 Introduction -- 2 Phenotypic Screening Techniques for Major Diseases of Rice: Pathogen Inoculum, Plant Infection Assays, and Disease Scoring -- 2.1 Bacterial Blight -- 2.2 Blast Disease -- 2.3 Sheath Blight -- 2.4 Sheath Rot of Rice -- 2.5 False Smut -- 2.6 Tungro Disease of Rice -- 2.7 Bacterial Leaf Streak -- 3 Genetics of Disease Resistance -- 4 Breeding for Disease Resistance -- 4.1 MAS/MABB Foreground/Background Selection -- 4.2 Pyramiding Disease-Resistance Genes -- 4.3 Varieties Improved and Developed -- 4.4 Multiple Disease-Resistance Breeding Strategies -- 5 Molecular Mechanisms of Disease Resistance -- 5.1 Resistance to Bacterial Blight -- 5.2 Resistance to Bacterial Leaf Streak -- 5.3 Resistance to Rice Blast -- 5.4 Resistance to Sheath Blight -- 5.5 Broad-Spectrum Resistance Genes -- 6 Impact of Major Nutrient Fertilizers on Biotic Disease Resistance in Rice -- 7 Genome-Editing Tools for Improving Disease Resistance -- 7.1 Site-Specific Mutagenesis: The Path So Far.
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|a 7.1.1 Meganucleases.
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|a Description based on publisher supplied metadata and other sources.
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|a Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2023. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries.
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|a Electronic books.
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|a Wani, Shabir Hussain.
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|i Print version:
|a Ali, Jauhar
|t Rice Improvement
|d Cham : Springer International Publishing AG,c2021
|z 9783030665296
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| 797 |
2 |
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|a ProQuest (Firm)
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| 856 |
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|u https://ebookcentral.proquest.com/lib/matrademy/detail.action?docID=6606585
|z Click to View
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