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.…mehr
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 sensiblydesigned 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
Dr. Shabir Hussain Wani is senior Assistant professor at Mountain Research Centre for Field Crops, Khudwani -192101, Sher-e-Kashmir University of Agricultural Sciences and Technology of Kashmir, J&K, India. He received Ph.D. degree in plant breeding and genetics on "transgenic rice for abiotic stress tolerance" from the Punjab Agricultural University Ludhiana, India. After obtaining his Ph.D. he worked as research associate in the Biotechnology Laboratory, Central Institute of Temperate Horticulture (ICAR), Srinagar, India. He then joined the Krishi Vigyan Kendra (Farm Science Centre) as program coordinator at Senapati, Manipur, India. He teaches courses related to plant breeding, seed science and technology, and stress breeding and has published more than 100 papers/chapters in journals and books of international and national repute. He served as guest editor and reviews editor for journal Frontier in Plant Science (2015-2018). He has also edited several books on current topics in crop improvement for abiotic stress tolerance published by Springer Nature and CRC press USA. His Ph.D. research fetched first prize in the North Zone Competition, at national level, in India. He was awarded Young Scientist Award from the Society for Promotion of Plant Sciences, Jaipur, India, in 2009. He is a fellow of the Society for Plant Research, India. Recently he also received Young Scientist Award (Agriculture) 2015 from Society for Plant Research, Meerut, India. He also served as visiting Scientist at Department of Plant Soil and Microbial Sciences, Michigan State University, USA under the UGC Raman Post Doctoral Fellowship programme. Currently, he is in charge of Wheat improvement programme at MRCFC Khudwani SKAUST Kashmir.
Inhaltsangabe
1. Maize Genome Genome diversity in Maize.- 2. Maize biodiversity: state of the art and future perspective for breeding.- 3. European maize landraces made accessible for plant breeding and genome-based studies.- 4.Maize genome analysis to elucidate evolution with time.- 5. QTL mapping for high temperature stress in Maize.- 6. QTL mapping advances for European Corn Borer Resistance in maize.- 7. GWAS for maize yield Improvement.- 8. Transcriptional Factor; a molecular switch to adapt Abiotic Stress mechanism in maize.- 9. Gene expression Divergence in Maize.- 10. Physiological and Biochemical Responses of Maize under Drought Stress.- 11. Fungal Pathogen Induced Modulation of Structural and Functional Proteins in Zea mays.- 12.Maize improvement using recent Omics approaches.- 13. Molecular Genetic Approaches to Maize Improvement..- 14. Genomic selection in maize improvement.- 15. Genetic engineering for improvement of qualitative and quantitative traits in Maize.- 16. Potential of phenomics in climate resilient maize breeding.- 17. Current Genomic Approaches for biotic stress tolerance in Maize.- 18. Genomics approaches for ascertaining Drought stress responses in Maize.- 19. Genotyping advances for Heat stress Tolerance in Maize.- 20. Biofortification in Maize through Marker Assisted Breeding.- 21. Molecular breeding approaches to improve NUE in Maize.- 22. Molecular breeding (QTL mapping) for Phosphorus Use Efficiency in Maize.- 23. Maize improvement for water use efficiency: Advances in Recent molecular marker technology.- 24. Genome editing Advances for Maize Improvement.
1. Maize Genome Genome diversity in Maize.- 2. Maize biodiversity: state of the art and future perspective for breeding.- 3. European maize landraces made accessible for plant breeding and genome-based studies.- 4.Maize genome analysis to elucidate evolution with time.- 5. QTL mapping for high temperature stress in Maize.- 6. QTL mapping advances for European Corn Borer Resistance in maize.- 7. GWAS for maize yield Improvement.- 8. Transcriptional Factor; a molecular switch to adapt Abiotic Stress mechanism in maize.- 9. Gene expression Divergence in Maize.- 10. Physiological and Biochemical Responses of Maize under Drought Stress.- 11. Fungal Pathogen Induced Modulation of Structural and Functional Proteins in Zea mays.- 12.Maize improvement using recent Omics approaches.- 13. Molecular Genetic Approaches to Maize Improvement..- 14. Genomic selection in maize improvement.- 15. Genetic engineering for improvement of qualitative and quantitative traits in Maize.- 16. Potential of phenomics in climate resilient maize breeding.- 17. Current Genomic Approaches for biotic stress tolerance in Maize.- 18. Genomics approaches for ascertaining Drought stress responses in Maize.- 19. Genotyping advances for Heat stress Tolerance in Maize.- 20. Biofortification in Maize through Marker Assisted Breeding.- 21. Molecular breeding approaches to improve NUE in Maize.- 22. Molecular breeding (QTL mapping) for Phosphorus Use Efficiency in Maize.- 23. Maize improvement for water use efficiency: Advances in Recent molecular marker technology.- 24. Genome editing Advances for Maize Improvement.
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