Legumes under environmental stress yield, improvement and adaptations
The improvement of crop species has long been a goal since cultivation began thousands of years ago. To feed an ever increasing world population will require a great increase in food production. Wheat, corn, rice, potato and legumes are expected to lead as the most important crops in the world. Due...
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| Formato: | Libro electrónico |
| Idioma: | Inglés |
| Publicado: |
Hoboken, NJ :
John Wiley & Sons Inc
2015.
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| Colección: | Wiley ebooks.
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| Acceso en línea: | Conectar con la versión electrónica |
| Ver en Universidad de Navarra: | https://innopac.unav.es/record=b46127781*spi |
Tabla de Contenidos:
- Legumes under Environmental Stress: Yield, Improvement and Adaptations; Copyright; Contents; List of contributors; Preface; About the editors; Chapter 1 Legumes and breeding under abiotic stress: An overview; 1.1 Introduction; 1.2 Legumes under abiotic stress; 1.2.1 Legumes under drought; 1.2.2 Legumes under salinity; 1.2.3 Legumes under waterlogging; 1.2.4 Legumes under temperature extremes; 1.2.5 Legumes under soil acidity; 1.2.6 Legumes under nutrient deficiency; 1.3 Breeding of cool season food legumes; 1.4 Breeding of cool season food legumes under abiotic stress.
- 1.5 Breeding of warm season food legumes1.6 Breeding of warm season food legumes under abiotic stress; 1.6.1 Short duration and photo-thermal insensitivity; 1.6.2 Leaf pubescence density; 1.6.3 Seed dormancy; 1.6.4 Deep root system; 1.7 Biotechnology approaches; 1.7.1 MicroRNAs; 1.7.2 Molecular marker-assisted breeding; 1.7.3 Gene pyramiding assisted by MAS; 1.7.4 Somaclonal variation and in vitro mutagenesis; 1.7.5 In vitro selection; 1.7.6 Transcriptomics; 1.7.7 Proteomics; 1.7.8 Transgenomics; 1.7.9 Targeting induced local lesions in genomes (TILLING); 1.8 Conclusions and future prospects.
- 3.2 Environmental stresses and crop growth3.2.1 Drought and salt stresses; 3.2.2 Heavy metal stress; 3.2.3 Heat and cold stresses; 3.2.4 Oxidative stress; 3.3 Effects of nutrient deficiency; 3.4 Methods to control nutrient deficiency; 3.5 Micronutrient deficiency in plants; 3.5.1 Boron; 3.5.2 Molybdenum; 3.5.3 Cobalt; 3.5.4 Copper; 3.5.5 Zinc; 3.5.6 Iron; 3.5.7 Manganese; 3.5.8 Nickel; 3.6 Roles of macronutrients in growth of legumes; 3.6.1 Role of carbon; 3.6.2 Role of nitrogen; 3.6.3 Role of phosphorus; 3.6.4 Role of sulphur; 3.6.5 Role of potassium.
- 3.7 Storage proteins in legumes and effect of nutritional deficiency3.8 Protective mechanisms triggered in legumes under stress; 3.8.1 Drought and salinity stress; 3.8.2 Cold stress; 3.9 Conclusion; References; Chapter 4 Chickpea: Role and responses under abiotic and biotic stress; 4.1 Introduction; 4.2 Origin and occurrence; 4.3 General botany; 4.4 Nutritional uses; 4.5 Abiotic stress; 4.6 Chickpea and abiotic stress: The 'omics' approach; 4.6.1 Proteomics; 4.6.2 Transcriptomics; 4.6.3 Genomics; 4.6.4 Transgenomics; 4.7 Biotic stress; 4.7.1 Chickpea and diseases.
