LEADER 11089nam 2200505 450 001 9910556894703321 005 20221110090334.0 010 $a9783030910396$b(electronic bk.) 010 $z9783030910389 035 $a(MiAaPQ)EBC6938780 035 $a(Au-PeEL)EBL6938780 035 $a(CKB)21419811900041 035 $a(PPN)261524186 035 $a(EXLCZ)9921419811900041 100 $a20221110d2022 uy 0 101 0 $aeng 135 $aurcnu|||||||| 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 00$aGenomic designing for abiotic stress resistant pulse crops /$fChittaranjan Kole, editor 210 1$aCham, Switzerland :$cSpringer,$d[2022] 210 4$d©2022 215 $a1 online resource (399 pages) 311 08$aPrint version: Kole, Chittaranjan Genomic Designing for Abiotic Stress Resistant Pulse Crops Cham : Springer International Publishing AG,c2022 9783030910389 327 $aIntro -- Preface -- Contents -- Contributors -- Abbreviations -- 1 Designing Common Bean (Phaseolus vulgaris L.) for Abiotic Stress Tolerance -- 1.1 Introduction -- 1.2 Genetic Resources of Abiotic Stress Tolerance -- 1.3 Molecular Mapping of QTLs Underlying Abiotic Stress Tolerance -- 1.4 Genomic and Transcriptomic Resources -- 1.5 Prospects and Conclusions -- References -- 2 A Scintillating Journey of Genomics in Simplifying Complex Traits and Development of Abiotic Stress Resilient Chickpeas -- 2.1 Introduction -- 2.2 Abiotic Stresses Affecting Chickpea -- 2.2.1 Drought Stress -- 2.2.2 Heat Stress -- 2.2.3 Cold Stress -- 2.2.4 Salinity Stress -- 2.3 Advancements in Genomics to Combat Abiotic Stress in Chickpea -- 2.4 Application of Transgenic Technology to Combat Abiotic Stresses in Chickpea -- 2.5 Chickpea Molecular Breeding Lines Released Using Genomic Tools -- 2.6 Application of Novel Breeding Approaches for Accelerating Abiotic Stress Tolerance in Chickpea -- 2.6.1 Multi-parent Populations -- 2.6.2 Speed Breeding -- 2.7 Emerging Stresses in the Context of Climate Change -- 2.8 Conclusions and Future Perspectives -- References -- 3 Genomic Designing for Abiotic Stress Tolerance in Pea (Pisum Sativum L.) -- 3.1 Introduction -- 3.2 Key Abiotic Stresses -- 3.2.1 Heat Stress -- 3.2.2 Cold Stress -- 3.2.3 Drought Stress -- 3.2.4 Salinity -- 3.2.5 Waterlogging -- 3.2.6 Nutrient Use Efficiency -- 3.3 Genetic Resources -- 3.3.1 Primary and Secondary Gene Pool -- 3.3.2 Tertiary Gene Pool -- 3.4 Conventional Breeding for Abiotic Stress Resistance -- 3.5 Limitations of Conventional Breeding -- 3.6 Diversity Exploration -- 3.6.1 Phenotype-Based Diversity Analysis -- 3.6.2 Genotype-Based Diversity Analysis -- 3.7 Crop Wild Relatives -- 3.7.1 CWR and Their Geographical Distribution -- 3.7.2 Extent of Genetic Diversity in CWR. 327 $a3.8 Association Mapping Studies -- 3.8.1 Linkage Disequilibrium (LD) -- 3.8.2 Target Gene-Based LD Studies -- 3.8.3 Genome-Wide LD Studies -- 3.8.4 Potential of Association Studies for Genetic Enhancement -- 3.9 Molecular Mapping of Resistance and Quantitative Trait Loci -- 3.9.1 Mapping Software Used -- 3.9.2 Classical Mapping Efforts -- 3.9.3 QTL Mapping -- 3.9.4 Mendelization of QTLs -- 3.10 Marker Assisted Breeding (MAB) for Resistance Traits -- 3.10.1 Marker-Assisted Gene Introgression -- 3.10.2 Gene Pyramiding (GP) -- 3.10.3 Limitations of Marker Assisted Selection -- 3.11 Map-Based Cloning of Resistance/Tolerance Genes/QTLs -- 3.11.1 Traits and Genes -- 3.11.2 Genomic Libraries -- 3.11.3 Test for Expression -- 3.12 Genomics Assisted Breeding -- 3.12.1 Genetic Resources -- 3.12.2 Genome Sequencing -- 3.12.3 Gene Annotation -- 3.12.4 Genomics Assisted Breeding Applications -- 3.13 Recent Concepts and Strategies -- 3.13.1 Targeting Induced Local Lesions in Genomes (TILLING) -- 3.13.2 Gene Editing -- 3.13.3 Nanotechnology -- 3.14 Genetic Engineering for Resistance/Tolerance Traits -- 3.14.1 Gene Transformation -- 3.14.2 Organelle Transformation -- 3.14.3 Gene Stacking -- 3.14.4 Gene Silencing -- 3.14.5 Prospects of Cisgenics -- 3.15 Bioinformatics Tools -- 3.15.1 Gene and Genome Database -- 3.15.2 Gene Expression Database -- 3.15.3 Comparative Genome Database -- 3.15.4 Protein or Metabolomics Database -- 3.16 Social, Political and Regulatory Issues -- 3.16.1 Patent and Intellectual Property Rights -- 3.16.2 Traditional Knowledge -- 3.16.3 Participatory Breeding -- 3.17 Future Perspectives -- References -- 4 Advanced Breeding Strategies for Abiotic Stress Tolerance in Cowpea -- 4.1 Introduction -- 4.2 Available Germplasm -- 4.3 Abiotic Stress Tolerance Related Traits -- 4.3.1 Root Characters -- 4.3.2 Heat and Cold Tolerance. 327 $a4.3.3 Drought Tolerance -- 4.3.4 Salinity Tolerance -- 4.3.5 Herbicide Tolerance -- 4.3.6 Nutrient Use Efficiency -- 4.3.7 Aluminium Toxicity -- 4.4 Sources of Abiotic Stress Tolerance Genes -- 4.5 Genetic Diversity Analysis -- 4.5.1 Phenotype-Based Diversity Analysis -- 4.5.2 Genotype-Based Diversity Analysis Based on Molecular Marker Studies -- 4.5.3 Molecular Mapping in Cowpea for Abiotic Stress Resistance -- 4.5.4 Molecular Breeding -- 4.5.5 Genomics Assisted Breeding -- 4.6 Classical Genetics and Traditional Breeding for Abiotic Stress Tolerance -- 4.6.1 Heat and Cold Tolerance -- 4.6.2 Root Characters and Drought Tolerance -- 4.6.3 Salinity and Aluminium Tolerance -- 4.6.4 Herbicide Tolerance -- 4.7 Needs in Breeding and Genetics of Cowpea -- 4.8 Future Prospects in Genetic Improvement -- References -- 5 Breeding for Abiotic Stress Tolerance in Lentil in Genomic Era -- 5.1 Introduction -- 5.1.1 Nutritional Value of Lentil -- 5.1.2 Reduction in Yield and Quality Due to Stress -- 5.1.3 Morphological Traits for Improving Productivity -- 5.1.4 Growing Importance in the Face of Climate Change and Increasing Population -- 5.2 Abiotic Stresses Affecting Lentil -- 5.2.1 Heat Tolerance -- 5.2.2 Cold Tolerance -- 5.2.3 Drought Tolerance -- 5.2.4 Flooding and Submergence Tolerance -- 5.2.5 Salinity Tolerance -- 5.3 Lentil Wild Relatives as a Source of Tolerance to Abiotic Stress -- 5.4 Genetic Diversity Studies in Lentil -- 5.5 Next Generation Technologies as a Platform for Genomics Aided Breeding -- 5.6 Transcriptome Analysis of Lentil in Response to Abiotic Stresses -- 5.7 Molecular Mapping of Tolerance Genes and QTLs -- 5.8 Marker-Assisted Selection (MAS) in Lentil -- 5.9 Conclusion -- References -- 6 Genomic Design for Abiotic Stress Resistance in Pigeonpea -- 6.1 Introduction -- 6.1.1 Economic Importance of the Crop. 327 $a6.1.2 Reduction in Yield and Quality Due to Abiotic Stresses -- 6.1.3 Importance in the Era of Changing Climate and Growing Population -- 6.1.4 Limitations of Traditional Breeding and Rational of Genome Designing -- 6.2 Descriptions of Different Abiotic Stresses -- 6.2.1 Drought Resistance -- 6.2.2 Waterlogging -- 6.2.3 Salinity Tolerance -- 6.2.4 Temperature Tolerance -- 6.2.5 Photoperiod -- 6.2.6 Al Toxicity -- 6.2.7 Traditional Breeding -- 6.2.8 Limitations and Prospect of Genomic Designing -- 6.3 Genetic Resources of Resistance/Tolerance Genes -- 6.3.1 Primary Gene Pool (GP1) -- 6.3.2 Secondary Gene Pool (GP2) -- 6.3.3 Tertiary Gene Pool (GP3) -- 6.4 Glimpses on Classical Genetics and Traditional Breeding -- 6.4.1 Classical Mapping Efforts -- 6.4.2 Limitations of Classical Endeavors and Utility of Molecular Mapping -- 6.4.3 Breeding Objectives -- 6.4.4 Classical Breeding Achievements -- 6.4.5 Limitations of Traditional Breeding and Rationale for Molecular Breeding -- 6.5 Diversity Analysis in Pigeonpea -- 6.5.1 Phenotype-Based Diversity Analysis -- 6.5.2 Genotype-Based Diversity Analysis -- 6.5.3 Relationship with Other Cultivated and Wild Species -- 6.5.4 Relationship with Geographical Distribution -- 6.5.5 Extent of Genetic Diversity -- 6.6 Molecular Mapping of Resistance Genes and QTLs -- 6.6.1 Brief History of Mapping Efforts in Pigeonpea -- 6.6.2 Evolution of Marker Types -- 6.6.3 Mapping Populations Used -- 6.6.4 Association Mapping -- 6.6.5 Trait Mapping -- 6.6.6 Next-Generation Based Trait Mapping -- 6.7 Marker-Assisted Breeding for Resistance Traits -- 6.7.1 Germplasm Characterization and DUS -- 6.7.2 Marker-Assisted Gene Introgression -- 6.7.3 Gene Pyramiding -- 6.7.4 Limitations and Prospects of MAS and MABCB -- 6.8 Map-Based Cloning of Resistance Genes -- 6.8.1 Traits and Genes Targeted for Map-Based Cloning. 327 $a6.8.2 BAC Library for Cloning -- 6.8.3 Expression of Cloned Genes -- 6.9 Genomics-Aided Breeding for Resistance -- 6.9.1 Details of Genome Sequencing -- 6.9.2 Organelle Sequencing -- 6.9.3 Application of Genomics-Assisted Breeding -- 6.10 Recent Concepts and Strategies Developed -- 6.10.1 Gene Editing -- 6.10.2 Nanotechnology -- 6.11 Genetic Engineering for Resistance -- 6.11.1 Transgenic Achievements in Pigeonpea -- 6.11.2 Genetic Resources in Pigeonpea for Development of Abiotic Stress Tolerant Transgenic Plant -- 6.11.3 Transgenic Pigeonpea Development for Abiotic Stress Tolerance -- 6.11.4 Future Prospects -- 6.12 Brief Accounts on Role of Bioinformatics as a Tool -- 6.12.1 Genomic Resources -- 6.12.2 Comprehensive Transcriptomic Resources -- 6.13 Brief Account on Social, Political and Regulatory Issues -- 6.13.1 Patent and Intellectual Property Rights (IPR) Issues -- 6.13.2 Farmers Right -- 6.13.3 Participatory Plant Breeding (PPB) -- 6.14 Future Perspectives -- 6.14.1 Potential for Expansion of Productivity -- 6.14.2 Potential for Expansion into Nontraditional Areas -- References -- 7 Genetic and Genomic Research for Abiotic Stresses in Faba Bean -- 7.1 Introduction -- 7.2 Major Abiotic Stresses -- 7.2.1 Cold Stress -- 7.2.2 Heat Stress -- 7.2.3 Drought Stress -- 7.2.4 Acidic Soils -- 7.2.5 Soil Salinity -- 7.3 Breeding Efforts -- 7.3.1 Cold Tolerance -- 7.3.2 Heat Tolerance -- 7.3.3 Drought Tolerance -- 7.3.4 Tolerance to Acidic Soils -- 7.3.5 Tolerance to Salinity -- 7.4 Genetic Resources and Diversity -- 7.5 Traditional Breeding Methods -- 7.6 Speed Breeding -- 7.7 Genetic and Genomics Research -- 7.8 Conclusions and Future Direction -- References -- 8 Genomic Designing for Abiotic Stress Tolerance in Mungbean and Urdbean -- 8.1 Introduction -- 8.1.1 Economic Importance -- 8.1.2 Reductions in Yield and Quality Due to Abiotic Stresses. 327 $a8.1.3 Growing Importance in the Face of Climate Change and Increasing Population. 606 $aCrop improvement 606 $aLegumes$xBiotechnology 606 $aLegumes$xEffect of stress on 615 0$aCrop improvement. 615 0$aLegumes$xBiotechnology. 615 0$aLegumes$xEffect of stress on. 676 $a631.5233 702 $aKole$b Chittaranjan 801 0$bMiAaPQ 801 1$bMiAaPQ 801 2$bMiAaPQ 912 $a9910556894703321 996 $aGenomic designing for abiotic stress resistant pulse crops$92968986 997 $aUNINA