Maize Improvement: Current Advances in Yield, Quality, and Stress Tolerance under Changing Climatic Scenarios

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Maize is one of the most generally grown cereal crops at global level, followed by wheat and rice. Maize is the major crop in China both in terms of yield and acreage. In 2012, worldwide maize production was about 840 million tons. Maize has long been a staple food of most of the global population (particularly in South America and Africa) and a key nutrient resource for animal feed and for food industrial materials. Maize belts vary from the latitude 58° north to the latitude 40° south, and maize ripens every month of the year. Abiotic and biotic stresses are common in maize belts worldwide. Abiotic stresses (chiefly drought, salinity, and extreme temperatures), together with biotic stresses (primarily fungi, viruses, and pests), negatively affect maize growth, development, production and productivity. In the recent past, intense droughts, waterlogging, and extreme temperatures have relentlessly affected maize growth and yield. In China, 60% of the maize planting area is prone to drought, and the resultant yield loss is 20%–30% per year; in India, 25%–30% of the maize yield is lost as a result of waterlogging each year. The biotic stresses on maize are chiefly pathogens (fungal, bacterial, and viral), and the consequential syndromes, like ear/stalk rot, rough dwarf disease, and northern leaf blight, are widespread and result in grave damage. Roughly 10% of the global maize yield is lost each year as a result of biotic stresses. For example, the European corn borer [ECB, Ostrinianubilalis (Hübner)] causes yield losses of up to 2000 million dollars annually in the USA alone in the northern regions of China, the maize yield loss reaches 50% during years when maize badly affected by northern leaf blight. In addition, abiotic and biotic stresses time and again are present at the same time and rigorously influence maize production. To fulfill requirements of each maize-growing situation and to tackle the above mentions stresses in an effective way sensibly designed multidisciplinary strategy for developing suitable varieties for each of these stresses has been attempted during the last decade.  Genomics is a field of supreme significance for elucidating the genetic architecture of complex quantitative traits and characterizing germplasm collections to achieve precise and specific manipulation of desirable alleles/genes. Advances in genotyping technologies and high throughput phenomics approaches have resulted in accelerated crop improvement like genomic selection, speed breeding, particularly in maize.  Molecular breeding tools like collaborating all omics, has led to the development of maize genotypes having higher yields, improved quality and resilience to biotic and abiotic stresses. Through this book, we bring into one volume the various important aspects of maize improvement and the recent technological advances in development of maize genotypes with high yield, high quality and resilience to biotic and abiotic stresses

Author(s): Shabir Hussain Wani, Zahoor Ahmad Dar, Gyanendra Pratap Singh
Publisher: Springer
Year: 2023

Language: English
Pages: 337
City: Cham

Contents
Genome Diversity in Maize
1 Introduction
2 Landraces of Maize
3 Genome of Maize
4 Intraspecific and Intergenic Diversity of Maize
4.1 Interspecific Crosses
4.2 Intergeneric Crosses
5 Maize Genome Evolution and Diversity
6 Concluding Remarks
References
Advancement in QTL Mapping to Develop Resistance Against European Corn Borer (ECB) in Maize
1 Introduction
2 European Corn Borer (ECB), Ostrinia nubilalis (Hübner 1796)
3 Damages of ECB in Maize
4 Conventional and Transgenic Methods to Control ECB
5 Advances in QTL Mapping for ECB Resistance in Maize
6 Summary
References
Dissection of QTLs for Biotic Stress Resistance in Maize
1 Introduction
2 Biotic Stresses: Types, Major Symptoms and Losses Caused
2.1 Major Diseases
Fungal Diseases
Viral Diseases
2.2 Major Insect Pests
3 Defence Mechanisms in Maize Against Pathogens and Insects
3.1 Phytoalexins
3.2 Phytoanticipins
4 QTL Analysis for Biotic Stresses
4.1 Turcicum Leaf Blight/Northern Corn Leaf Blight
4.2 Gibberella Ear Rot (GER)
4.3 Diplodia Ear Rot (DER)
4.4 Fusarium Ear Rot (FER)
4.5 Stalk Rot
4.6 Maize Rough Dwarf Disease (MRDD)
4.7 Sugarcane Mosaic Virus (SCMV) Disease
4.8 Grey Leaf Spot (GLS)
4.9 Southern Corn Leaf Blight (SCLB)
5 QTLs for Insect Resistance
5.1 Mediterranean Corn Borer (MCB)
5.2 European Corn Borer (ECB)
5.3 Southwestern Corn Borer (SWCB)
5.4 Fall Armyworm (FAW)
5.5 Maize Weevil (MW)
6 Qualitative Resistance: R Genes
7 Utilization of QTLs Identified in MAS Programmes
8 Conclusion
References
Genome-Wide Association Studies (GWAS) for Agronomic Traits in Maize
1 Introduction
2 Natural Variations
3 Natural Variations in Maize
4 Evolution of Germplasm Characterization Methods in Maize
5 Association Mapping
6 Genome-Wide Association Studies
7 Significance of Population Structure for GWAS
8 Phenotyping
9 Genotyping
10 Next-Generation-Based Genotyping
11 GWAS in Maize
12 Identification of Various Candidate Genes Through GWAS in Maize
13 Conclusion
References
Genomic Selection in Maize Breeding
1 Introduction
2 GS in Maize for Biomass, Yield, and Yield-Related Traits
2.1 Prediction of Per Se and Hybrid Performance in Segregating Generations
2.2 GS in Inbred Lines
2.3 GS for Double Haploid-Based Breeding Programs
2.4 Rapid Cycling Genomic Selection
3 GS for Abiotic and Biotic Stress Tolerance
4 GS for Pre-breeding
5 Take-Home Message
References
Transcriptional Factor: A Molecular Switch to Adapt Abiotic Stress Mechanisms in Maize
1 Introduction
2 Transcriptional Factors
3 TFs and the Specific Target Genes Involved in Abiotic Stress Tolerance in Maize
3.1 MYC and MYB Regulon
4 The AP2 and EREBP Regulons
5 NAC Transcriptional Factors and Regulons
6 bZIP TFs: AREB/ABF Regulon
7 Alternative TFs and Their Regulons
8 Designing of TFs
9 Post-genomics and Current Approaches
10 Conclusion
References
Physiological and Biochemical Responses in Maize under Drought Stress
1 Introduction
2 Morpho-physiological Changes Under Drought Stress
2.1 Priming Improved Physiological Process
2.2 Effect of Drought and Recovery Period on Maize
2.3 Physiological Changes in Vegetative/Reproductive Phase Under Drought
3 Biochemical Changes Under Drought Stress
3.1 Metabolic Changes and Oxidative Defense Mechanism for Drought Tolerance
3.2 Priming Improves Biochemical Mechanism of Drought Tolerance
4 Role of Biotic Factors to Modify Physiological and Biochemical Process in Drought Tolerance
5 Conclusions and Future Prospects
References
Current Biotechnological Approaches in Maize Improvement
1 Introduction
2 Recent Improvement in Maize Production
3 Molecular Marker Technology
3.1 Germplasm Characterization
3.2 Pedigree Records Verification
3.3 Assigning Inbreeds to Heterotic Groups
3.4 Understanding the Basis and Heterosis Prediction
3.5 Identification and Localization of Gene
3.6 Marker-Assisted Selection Breeding
4 Large-Scale Genomics for Trait-Specific Genes
5 Bioinformatics for Analyzing Genomic Data for Molecular Breeding
6 Genetic Modification Technologies for Improvement of Maize
6.1 Genetic Transformation
6.2 Genome Editing for Precision Breeding
6.3 Commercialization of Transgenic Maize and Its Consequences
7 Application of Nanobiotechnology
8 Future Perspectives and Concluding Remarks
References
Advances in Genome Editing for Maize Improvement
1 Introduction
2 Significance of Maize and Global Status
3 Genome Editing
4 Meganucleases (MegaN)
5 Zinc Finger Nucleases (ZFNs)
6 Transcription Activator-Like Effector Nucleases (TALENs)
7 CRISPR/Cas9: A Robust Genome Editing Tool
8 Applications of CRISPR Cas9 in Maize Improvement
9 Conclusion and Future Perspectives
References
Genetic Engineering to Improve Biotic and Abiotic Stress Tolerance in Maize (Zea mays L.)
1 Introduction
2 Present Status of Genetically Modified Maize
3 Acceptance and Impact of Genetically Modified Maize
4 Genetic Engineering Approaches to Develop Transgenic Maize
4.1 Development of Gene Construct
4.2 Plant Transformation Methods
4.3 Regulation of Gene Expression
5 Genetic Engineering of Maize for Stress Tolerance
5.1 Genetic Engineering to Improve the Biotic Stress Tolerance in Maize
Herbicide-Tolerant Transgenic Maize
Insect-Resistant Transgenic Maize
Disease-Resistant Transgenic Maize
5.2 Genetic Engineering to Improve the Abiotic Stress Tolerance in Maize
Drought Tolerance Transgenic Maize
Heat Tolerance Transgenic Maize
Salinity Tolerance Transgenic Maize
Cold Tolerance Transgenic Maize
Waterlogging Tolerance Transgenic Maize
6 Conclusion and Future Perspectives
References
Genetic Improvement of Specialty Corn for Nutritional Quality Traits
1 Introduction
1.1 Sweet Corn
1.2 Popcorn
1.3 Waxy Corn
1.4 High Amylose Maize
1.5 High Oil Maize
1.6 Colored Corn
1.7 Baby Corn
2 Challenges and Future Prospects
References
Advances in High-Throughput Phenotyping of Maize (Zea Mays L.) for Climate Resilience
1 Introduction
2 Phenotype
2.1 Phenotyping
2.2 Types of Phenotyping
Forward Phenotyping
Reverse Phenotyping
3 Scope for Phenotyping Plant Responses
3.1 Phenotyping for Productivity
3.2 Phenotyping for Biotic Stress
3.3 Phenotyping for Abiotic Stress
3.4 Phenotyping for Quality Traits
4 Phenomics
5 Phenomic Tools
5.1 Post-Harvest Phenotyping Tools
5.2 Pocket Phenotyping Tools
5.3 Root Phenotyping Tools
6 Phenomics Platforms
6.1 Controlled Environments
6.2 Field Phenotyping
Ground-Based Phenomics Tools
Arial Platforms
7 Data Management and Analysis Tools
8 Integration of High-Throughput Phenotyping and Genomic Approaches in Maize
9 Conclusion and Future Prospectives
References
Maize Improvement Using Recent Omics Approaches
1 Introduction
2 Genomics
3 Structural Genomics
4 Functional Genomics and Muta-Genomics
5 Epigenomics
6 Pangenomics
7 Transcriptomics
8 Proteomics
9 Metabolomics
10 Conclusion
References
Fungal Pathogen-Induced Modulation of Structural and Functional Proteins in Zea mays L.
1 Introduction
2 Maize Proteomics Against Fungal Infection
2.1 Storage Proteins
2.2 Detoxifying Enzymes
2.3 Stress-Related Proteins
2.4 Proteins Involved in Protein Synthesis, Folding, and Stabilization
2.5 Antifungal Proteins
Trypsin Inhibitor
Pathogenesis-Related Proteins
2.6 Proteins Involved in Secondary Metabolism
2.7 Proteins Involved in Energy-Producing Carbohydrate Metabolic Pathways
3 Concluding Remark and Future Prospects
References
Role of Plant Growth-Promoting Rhizobacteria Mitigating Drought Stress in Maize
1 Introduction
2 Plant Growth-Promoting Rhizobacteria
3 Mechanism of Drought Tolerance by PGPRs
3.1 PGPRs and Phytohormones
3.2 PGPRs and Mineral Uptake
3.3 PGPRs and Secondary Metabolites
3.4 PGPRs and Antioxidant Machinery
4 Role of PGPRs in Maize Plants Under Drought Condition
5 Conclusion
References