Agronomy and crop production Books

Book SynopsisCassava is a major tropical tuber crop found throughout the tropics (India, Oceania, Africa and Latin America). Hitherto, there has been no single text covering all aspects of cassava biology, production and utilization. This book fills that gap, representing the first comprehensive research level overview of this main staple crop. Chapters are written by leading experts in this field from all continents. The book is suitable for those working and researching in cassava, in both developed and developing countries, as well as advanced students.Table of ContentsPart 1: Origin, Distribution and Economic Importance 1.1: Origin and Taxonomy of Cassava, A C Allem, EMBRAPA, Brasilia 1.2: Cassava in South America and the Caribbean, G Henry, CIRAD, Brazil and C Hershey, Manheim, PA, USA 1.3: Cassava in Africa, R J Hillocks, Natural Resources Institute, Chatham, Maritime, Kent, UK 1.4: Cassava in Asia and the Pacific, I Onwueme, University of Technology, Papua New Guinea Part 2: Botany, Crop Physiology and Agronomy 2.1: Botany and Crop Physiology, A A Alvez, EMBRAPA-CNPMF, Cruz das Almas, Brazil 2.2: Agronomy and Cropping Systems, D Leihner, FAO, Rome, Italy 2.3: Mineral Nutrition and Fertilisation, R H Howeler, CIAT, Bangkok, Thailand Part 3: Genetics and Crop Improvement 3.1: Breeding for Crop Improvement, D L Jennings, Kent, UK and C Iglesias, Weaver Popcorn Co, New Richmond, Indiana, USA 3.2: Genetic Resources and Conservation, N Q Ng and S C Ng, IITA, Ibadan, Nigeria 3.3: Cassava Biotechnology, M Fregene, CIAT, Cali, Colombia and J Puonti-Kaerlas, ETH Zentrum, Zurich, Switzerland Part 4: Crop Protection 4.1: Arthropod Pests and IPM, A Bellotti, CIAT, Cali, Colombia 4.2: The Origins and Taxonomy of Cassava, L A Calvert, CIAT, Cali, Colombia and J M Thresh, Natural Resources Institute, Chatham, Maritime, Kent, UK 4.3: Bacterial, Fungal and Nematode Diseases, R J Hillocks, Natural Resources Institute, Chatham, Maritime, Kent, UK and K Wydra, Georg August Universitat, Gottingen, Germany Part 5: Crop Utilisation 5.1: Cassava Utilization, Storage and Small-scale Processing, A Westby, Natural Resources Institute, Chatham, Maritime, Kent, UK 5.2: Cassava in Food, Feed and Industry, C Balagopalan, Central Tuber Crops Research Institute, Kerala, India

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Book SynopsisUntil recently, the production of fruits by plants, their consumption by animals (frugivory) and the relevance of these to seed dispersal have attracted less attention than topics such as pollination biology. However, since the 1970s they have started to gain more prominence and now give rise to more research funding, seminal papers and international symposiums. This book contains chapters adapted from the Third International Symposium-Workshop on Frugivores and Seed Dispersal held in August 2000 in Rio Quente, Brazil.Table of ContentsI: Historical and Theoretical Perspectives 1: Maintenance of tree diversity in tropical forests, J Terborgh, N Pitman, M Silman, H Schichter, and P Nunez V. 2: Dissemination limitation and the origin and maintenance of species-rich tropical forests, E W Schupp, T Milleron and S E Russo 3: Assessing recruitment limitation: Concepts, methods, and case studies from a tropical forest , H C Muller-Landau, et al 4: Have frugivores influenced the evolution of fruit traits in New Zealand? J M Lord, A S Markey and J Marshall 5: Mechanistic models for tree seed dispersal by wind in dense forests and open landscapes, R Nathan, H S Horn, J Chave, and S A Levin 6: The role of vertebrates in the diversification of new world mistletoes, C Restrepo, S Sargent, D J Levey, and D M Watson II: Plant Strategies 7: Mistletoes as parasites and seed-dispersing birds as disease vectors: current understanding, challenges, and opportunities, J E Aukema and C Martínez del Rio 8: Secondary metabolites of ripe fleshy fruits: ecology and phylogeny in the genus Solanum, M L Cipollini, et al 9: The seed dispersers and fruit syndromes of Myrtaceae in the Brazilian Atlantic Forest, M A Pizo 10: Are plant species that need gaps for recruitment more attractive to seed-dispersing birds and ants than other species? C C Horvitz, et al 11: The role of fruit traits in determining fruit removal in east Mediterranean ecosystems, I Izhaki 12: Seed dispersal of mimetic fruits: parasitism, mutualism, or exaptation? M Galetti 13: Secondary dispersal of Jeffery pine seeds by rodent scatter hoarders: the roles of pilfering, recaching, and variable environment, S B VanderWall 14: The role of seed size in dispersal by a scatterhoarding rodent, P A Jansen, et al 15: Mast seeding and predator-mediated indirect interactions in a forest community: evidence from post- dispersal fate of rodent-generated caches, K Hoshizaki and P E Hulme III: Animal Strategies 14: Seasonality of fruiting and food hoarding by rodents in Neotropical forests: consequences for seed dispersal and seedling recruitment, P Forget, D S Hammond, T Milleron, and R Thomas 15: Seed eaters: seed dispersal, destruction, and demography, P E Hulme 16: Plant-animal co-evolution: Is it thwarted by spatial and temporal variation in animal foraging? C A Chapman and L J Chapman 17: The frugivorous diet of the maned wolf, Chrysocyon brachyurus in Brazil: ecology, and conservation, J C Motta jnr and K Martins IV: Consequences of Seed Dispersal 18: Frugivore-generated seed shadows: A landscape view of demographic and genetic effects, P Jordano and J A Godoy 19: Contributions of seed dispersal and demography to recruitment limitation in a Costa Rican cloud forest, K G Murray and J M Garcia-C 20: A meta-analysis of gut treatment on seed germination, A Traveset and M Verdú 21: Seed dispersal effectiveness by Cercopithecus monkeys: implications for seed input into degraded areas, B A Kaplin and J E Lambert 22: Exploring the link between animal frugivory and plant strategies: the case of primate fruit-processing and post-dispersal seed fate, J E Lambert V: Conservation, Biodiversity, and Management 23: Extinct pigeons and declining bat populations: Are large seeds still being dispersed in the tropical Pacific? K R McConkey and D R Drake 24: Potential consequences of extinction of frugivorous birds for shrubs of a tropical wet forest, B A Loiselle and J G Blake 25: Primate frugivory in two species-rich Neotropical Forests: implications for the demography of large-seeded plants in overhunted areas, C A Peres and M van Roosmalen 26: Patterns of fruit-frugivore interactions in two Atlantic Forest bird communities of southeastern Brazil: implications for conservation, W R Silva, P De Marco, É Hasui, and V S M Gomes 27: Limitations of animal seed dispersal for enhancing forest succession on degraded lands, R S Duncan and C A Chapman 28: Frugivory and seed dispersal in degraded tropical east Asian landscapes, R T Corlett 29: Behavioral and ecological considerations for managing bird damage to cultivated fruits, M L Avery 30: Harvest and management of forest fruits by humans: implications for fruit-frugivore interactions, S M Moegenburg

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Book SynopsisThis book includes keynote invited papers from the Third International Crop Science Congress held in Hamburg, Germany in August 2000. All papers have been prepared and revised within strict editorial guidelines to ensure that the work is a balanced review text that provides an overview of the major issues confronting crop science today and in the future. It therefore represents a suitable advanced textbook for students as well as offering research workers concise overviews of topics adjacent to their areas of research. Contributors include leading world authorities from Europe, North and South America, Africa, Asia and Australia.Table of ContentsPart 1: Facing the Growing Needs of Mankind 1: Food Security? We Are Losing Ground Fast! F W T Penning de Vries 2: The Future of World, National and Household Food Security, F Heidhues 3: Crop Science Research to Assure Food Security, K G Cassman 4: Modifying the Composition of Plant Foods for Better Human Health, R F Hurrell 5: Grasslands and Rangelands, R J Wilkins Part 2: Stress in Crops and Cropping Systems 6: Abiotic Stresses, Plant Reactions, and New Approaches Towards Understanding Stress Tolerance, H J Bohnert and R A Bressan 7: Plant Stress Factors - Their Impact on Productivity of Cropping Systems, U R Sangakkara 8: Optimizing Water Use, N C Turner 9: Abiotic Stresses and Staple Crops, G O Edmeades, M Cooper, R Lafitte, C Zinselmeier, J -M Ribaut, J E Habben, C Löffler, and M Bänziger 10: Biotic Stresses in Crops, R Nelson 11: Management of Complex Interactions for Growth Resources and of Biotic Stresses in Agroforestry, C K Ong and M R Rao Part 3: Diversity in Agroecosystems 12: Optimizing Crop Diversification, D J Connor 13: Biodiversity of Agroecosystems: Past, Present and Uncertain Future, P J Edwards and A Hilbeck 14: Conservation and Utilization of Biodiversity in the Andean Ecoregion, W W Collins 15: The Role of Landscape Heterogeneity in the Sustainability of Cropping Systems, J Baudry and F Papy Part 4: Designing Crops and Cropping Systems for the Future 16: Cropping Systems for the Future, J Boiffin, E Malezieux and D Picard 17: Will Yield Barriers Limit Future Rice Production? J E Sheehy 18: New Crops for the Twenty-first Century, J Janick 19: Plant Biotechnology - Methods, Goals, and Achievements, U Sonnewald and K Herbers 20: Transgenic Plants for Sustainable Crop Production, B Keller and E Hütter Carabias Part 5: Position Papers 21: Crop Science: Scientific and Ethical Challenges to Meet Human Needs, L O Fresco 22: Declaration of Hamburg, J H J Spiertz (ed)

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Book SynopsisIn the past twenty years there has been a revolution in plant sciences, as new methods of molecular biology and biophysics have been applied to investigate environmental stress, particularly desiccation tolerance. Today, there is a good level of understanding of how plant cells cope with extreme water stress. This book is divided into four sections, dealing with 1) the technical background to desiccation tolerance studies; 2) the frequency and levels of dehydration stress tolerance in biological systems; 3) mechanisms of damage and tolerance, and 4) a brief prospect and retrospect. It covers orthodox and recalcitrant seeds, pollen and spores, vegetative parts, and other plant tissues.Table of ContentsPart I: Introduction 1: Drying without dying, P Alpert and M J Oliver Part II: Methodology 2: Methods for study of water relations under desiccation stress, W K Sun 3: Experimental aspects of drying and recovery, N W Pammenter, P Berjak, J Wesley-Smith and C Vander Willigen 4: Biochemical and biophysical methods for quantifying desiccation phenomena in seeds and vegetative tissues, O Leprince and E Golovina Part III: Biology of dehydration 5: Desiccation sensitivity in orthodox and recalcitrant seeds in relation to development, A Kermode and B E Finch-Savage 6: Pollen and spores: Desiccation tolerance in pollen and the spores of lower plants and fungi, F A Hoekstra 7: Vegetative tissues: Bryophytes, vascular resurrection plants and vegetative propagules, M C F Proctor and V C Pence 8: Ecological, taxonomic and phylogenetic aspects of desiccation tolerance in seeds and other plant tissues, J Dickie and H Pritchard Part IV: Mechanisms of damage and tolerance 9: Desiccation stress and damage, C Walters, J M Farrant, N W Pammenter and P Berjak 10: Biochemistry and biophysics of tolerance systems, J Buitink, F A Hoekstra and O Leprince 11: Molecular genetics of desiccation and tolerant systems, J Phillips, M J Oliver and D Bartels 12: Rehydration of dried systems: Membranes and the nuclear genome, D J Osborne, I Boubriak and O Leprince Part V: Retrospect and prospect 13: Damage and tolerance in retrospect and prospect, M Black, H Pritchard and R Obendorf

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Book SynopsisRapid urbanization has created a major challenge with regard to waste management and environmental protection. However, the problem can be ameliorated by turning organic waste into compost for use as an agricultural fertilizer in peri-urban areas. This is especially significant in less developed countries, where food security is also a key issue. This book addresses these subjects and is based on papers presented at a workshop held in Ghana by the International Board for Soil Research and Management (IBSRAM, now part of the International Water Management Institute) and FAO. Special reference is given to Sub-Saharan Africa, with acknowledgement to experiences from other parts of the world. Contributing authors are from several European, as well as African, countries.Table of Contents1: The potential use of waste stream products for soil amelioration in peri-urban interface agricultural production systems, P J C Harris, M Allison, H G Smith, H M Kindness and J Kelley 2: Economic, sociocultural, and environmental considerations 3: The economic viability of organic waste composting, R G Niemeyer, H Litterscheidt and S Sanders 4: Assessing farmers' perceptions of organic wastes as nutrient sources, P Drechsel, C Quansah, Kwame Nkrumah and S Asante-Mensah 5: Environmental concerns of urban and peri-urban agriculture: Case studies from Accra and Kumasi, E Mensah, P Amoah, R C Abaidoo and P Drechsel 6: Turning urban waste into fertilizer for urban and peri-urban farmers: Case studies from East and West Africa 7: Turning municipal waste into compost: The case of Ibadan, T Agbola 8: Urban vegetable production in Lagos and Ibadan, M A O Oladokun 9: Turning municipal waste into compost: The case of Accra, I Etuah-Jackson, W P Klaassen and J A Awuye 10: Farming systems and farming inputs in and around Kumasi, K Nsiah-Gyabaah and M Adam 11: An integrated waste management strategy for Kumasi, L Salifu 12: Linking (peri-)urban agriculture and organic waste management in Dar es Salaam, S Kiango and J Amend 13: Urban agriculture in Lomé, M E A Schreurs and H van Reuler 14: Adding value to compost from urban household and market refuse in Lomé, A Kessler and J Helbig 15: Optimizing nutrient recycling and urban waste management - new concepts from Northern Europe, J Magid, A Dalsgaard and M Henze 16: Modelling urban and peri-urban biomass and nutrient flows 17: Assessing the potential of organic waste recycling through the analysis of rural-urban carbon fluxes, C Binder and N Patzel 18: The potential of co-composting in Kumasi - quantification of the urban and peri-urban nutrient balance, C Leitzinger 19: Estimating rural-urban nutrient flows for mega-cities, J Færge, J Magid and F Penning de Vries 20: Monitoring nutrient flows and economic performance in African farming systems: The NUTMON approach and its applicability to peri-urban agriculture, H van den Bosch, D Eaton, M S van Wijk, J Vlaming and A de Jager 21: Definition and boundaries of the peri-urban interface: Patterns in the patchwork, M G Adam 22: Urban agriculture: International support and capacity building in Africa, C J Sawio, L Spies and D Doucouré

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Book SynopsisSoil degradation and nutrient depletion have become serious threats to agricultural productivity in Africa. Soils cannot supply the quantities of nutrients required and yield levels decline rapidly once cropping commences. This book addresses these issues and includes papers from an international symposium held at Cotonou, Benin, October 9-12, 2000, organized by the International Institute of Tropical Agriculture, Ibadan, Nigeria and the Department of Land Management of the Katholieke Universiteit Leuven, Belgium. In five main parts it marks the end of a first phase of collaborative research on "Balanced Nutrient Management Systems for the Moist Savanna and Humid Forest Zones of Africa" and concludes with recommendations, providing essential reading for crop and soil scientists.Table of ContentsPart I: General Introduction 1: Forty years of soil fertility work in sub-Saharan Africa, R Dudal 2: Soil fertility replenishment takes off in East and Southern Africa, P A Sanchez and B A Jama Part II: Variability in biophysical and socio-economic factors and its consequences for selection of representative areas for nutrient balance experiments; possibilities and techniques for extrapolation 3: A systems approach to target balanced nutrient management in soil scapes, J Deckers 4: In for a penny, in for a pound: Strategic site-selection as a key element for on-farm research that aims to trigger sustainable agricultural intensification in West Africa, M E A Schreurs, A Maatman and C Danbégnon 5: Agricultural transformation and fertilizer use in the cereal-based systems of the northern Guinea savanna, Nigeria, V M Manyong, K O Makinde and A G O Oguingbile 6: Partial macro nutrient balances of mucuna/maize rotations in the Forest Savannah Transitional Zone of Ghana, J Anthofer and J Kroschel Part III: Soil processes determining nutrient dynamics, in particular nitrogen and phosphorus; modelling nutrient fluxes in tropical farming systems 7: Process research and soil fertility in Africa: who cares? R Merckx 8: Fertilizer equivalency values of organic materials of differing quality, H K Murwira, P Mutuo, N Nhamo, A E Marandu, R Rabeson, M Mwale and C A Palm 9: Plant N uptake from plant and animal organic residues, measured using the soil pre-labelling 15N isotope dilution approach, R Hood 10: Contribution or organic residues to soil phosphorus availability in the highlands of Western Kenya, G Nziguheba, R Merckx and C A Palm 11: Resource acquisition of mixed species fallows - competition or complementarity? G Cadisch, S Gathumbi, J K Ndufa and K E Giller Part IV: Interactions between organic and inorganic nutrient sources; functions of soil organic matter 12: Targeting management of organic resources and mineral fertilizers: Can we match scientists' fantasies with farmers' realities? K E Giller 13: Direct interactions between N fertilizer and organic matter: evidence from trials with N labelled fertilizer, B Vanlauwe, J Diels, K Aihou, E N O Iwuafor, O Lyasse, N Sanginga and R Merckx 14: On-farm evaluation of the contribution of sole and mixed applications of organic matter and urea to maize grain production in the savanna, E N O Iwuafor, K Aihou, J S Jaryum, B Vanlauwe, J Diels, N Sanginga, O Lyasse, J Deckers and R Merckx 15: Yields trends and soil nitrogen and organic matter content during twenty years of continuous maize cultivation, J Gigou and S K Bredoumy Part V: Improved utilisation of rock phosphate; capitalisation of soil phosphorus 16: Meeting the phosphorus needs of the soils and crops of West Africa: The role of indigenous phosphate rocks, U Mokwunye and A Bationo 17: Options for increasing P availability from low reactive rock phosphate, O Lyasse, B K Tossah, B Vanlauwe, J Diels, N Sanginga and R Merckx 18: Phosphorus (P) uptake from sparingly available soil-P by cowpea (Vigna unguiculata) genotypes, G Haar, T S Gahoonia, and N E Nielsen 19: Improving rock-P solubility and uptake and yields of lowland rice grown on acidic soil amended with legume green manure, E A Somado, R F Kuehne, M Bvecker, K L Sahrawat, and P L G. Viek Part VI: Decision support systems to improve fertilizer use efficiency at farm level; on-farm testing of technologies improving the soil nutrient balance 20: Decision making on integrated nutrient management through the eyes of the scientist, the land user and the policy maker, E M A Smaling, J J Stoorvogel and A de Jager 21: Legumes, when and where an option? (No panacea for poor tropical West African soils and expensive fertilizers), H Breman and H van Reuler 22: Options for soil organic carbon maintenance under intensive cropping in the West-African Savanna, J Diels, K Aihou, E N O Iwuafor, R Merckx, O Lyasse, N Sanginga, B Vanlauwe and J Deckers 23: On-farm research and operational strategies in soil fertility management, P L Woomer, E J Mukhwana and J K Lynam Part VII: Recommendations 24: Recommendations

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Book SynopsisThe cacao (Theobroma cacao) plant is an important Neo-Tropical species whose natural habitat is the Amazon basin. Over the last 30 years there has been a considerable geographical expansion in the availability of cacao genetic resources. As a result the plant has a rich genetic diversity that exists at two levels: that of the primitive populations in the area of original distribution of the species, and that of the derived cultivated populations. This book provides a comprehensive review of our current knowledge of the diversity of the species. It starts by examining the diversity and inheritance of the characteristics of primitive populations in the Amazonian and Caribbean regions. It then looks at the evolution of diversity within cultivated populations first in South America and around the Caribbean, and then beyond the Americas. The book describes the inter-relationships between populations based on morphological and molecular markers. It also examines the conservation of genetic rTable of Contents1: Foreword, Tony Lass 2: The Background to the Subject: Concepts and a Brief History 3: The Terminology Specific to Cacao 4: The Indicators of Variability 5: The Manifestation of the Diversity and its Conservation 6: The Foundations of the Diversity 7: The Amazonian Region 8: The Circum-Caribbean Region 9: The Cultivated Populations as Secondary Depositories of the Diversity 10: Introduction Part 1: South America - Populations Derived from an Amazonian Region Germplasm Base Part 2: The Circum-Caribbean Region and Neighbouring Territories Populations that Evolved from a Criollo Germplasm Base Part 3: Cacao Beyond the Americas - The Export 11: The Genetics of the Diversity 12: The Relationships among Populations 13: The Utilization of the Genetic Resources 14: Epilogue - Final Remarks

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Book SynopsisAs a result of editions published in 1993 and 1997, the Rice Almanac has become a standard handbook that brings together general information about rice and data about rice production worldwide. The third edition has been fully updated and expanded to include more countries, and is the result of collaboration between the International Rice Research Institute (IRRI), West Africa Rice Development Association (WARDA), Centro Internacional de Agricultura Tropical (CIAT) and the Food and Agriculture Organization (FAO) of the United States.Table of Contents1: Introduction 2: Origin and diffusion of rice 3: Genetic diversity of rice 4: Rice-growing areas 5: Rice production 6: Importance of Rice 7: Rice as human food 8: Speciality uses of rice 9: Morphology and Growth of the Rice Plant 10: Morphology 11: Wetlands and rice soils 12: Rice Environments 13: Agroecological zones 14: Irrigated rice ecosystem 15: Rainfed lowland rice ecosystem 16: Upland rice ecosystem 17: Flood-prone rice ecosystem 18: Friends and Enemies in the Fields 19: Pests 20: Friends 21: International Issues 22: The looming water crisis 23: Adding vitamin A and other micronutrients 24: Increasing yield potential 25: Functional genomics 26: Global climate change and rice 27: Emission of greenhouse gases from rice fields 28: Biotechnology issues 29: International Rice Research and Development 30: FAO’s role 31: International research centers 32: Rice around the World 33: Rice and Food Security in Asia 34: Rice in Europe and the Mediterranean 35: Rice in North America 36: Rice in Latin America and the Caribbean 37: Rice in West Africa 38: The Top 10 Rice-producing Countries 39: China 40: India 41: Indonesia 42: Bangladesh 43: Vietnam 44: Thailand 45: Myanmar 46: Japan 47: Philippines 48: Brazil 49: Rice in other Countries 50: Afghanistan 51: Argentina 52: Australia 53: Bhutan 54: Bolivia 55: Burkina Faso 56: Cambodia 57: Cameroon 58: Chad 59: Colombia 60: Congo DR 61: Côte d’Ivoire 62: Cuba 63: Dominican Republic 64: Ecuador 65: Egypt 66: France 67: Gambia 68: Ghana 69: Greece 70: Guinea 71: Guinea-Bissau 72: Guyana 73: Iran 74: Italy 75: Korea DPR 76: Korea, Republic of 77: Lao DPR 78: Liberia 79: Madagascar 80: Malaysia 81: Mali 82: Mauritania 83: Mexico 84: Mozambique 85: Nepal 86: Nicaragua 87: Niger 88: Nigeria 89: Pakistan 90: Paraguay 91: Peru 92: Portugal 93: Russian Federation 94: Senegal 95: Sierra Leone 96: Spain 97: Sri Lanka 98: Suriname 99: Tanzania 100: Turkey 101: USA 102: Uruguay 103: Venezuela 104: Rice-related Databases 105: Conversion Factors A: Appendix Tables

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Book SynopsisDescriptions of fruit varieties suitable for organic production Plant protection, pests and diseases and how they can be countered in organic systems Includes tables, diagrams graphs and photographsThere is great interest in organic horticulture and this title is a timely and much needed addition for practical, science-based guidance. It is a translation of a volume which has been very well received in German and is the product of collaboration between authors in Austria, Germany, Italy, the Netherlands and Switzerland. The contents include the basics of organic fruit growing, but also cover orchard construction, cultivation, protection and the commercialization of the organic products.Table of Contents1: Principles of organic fruit growing 2: General principles 3: Legal aspects 4: Conversion of a conventionally run production unit to organic fruit growing 5: Planning and setting up an organic production unit 6: Choice of site: ecological principles 7: Planting stock for an organic orchard 8: Planting systems in organic fruit production 9: Choice of rootstocks and cultivars in organic fruit production 10: Dessert apple production 11: Dessert pear production 12: Production of stone fruit (cherries and plums) 13: Organic production of small fruit 14: Cultural measures in organic fruit growing 15: Protection of the soil when using machinery 16: Care of the soil 17: Fertilizer application 18: Important organic fertilizers for fruit growing 19: Thinning in organic fruit growing 20: Growth-regulating measures in organic fruit growing 21: Plant protection 22: Principles and aims of organic plant protection 23: Encouraging biodiversity in orchards 24: Beneficials, or taking advantage of natural regulation 25: Major diseases and pests of pome fruit 26: Major diseases and pests of stone fruit 27: Major diseases and pests of strawberries 28: Major diseases and pests of raspberries 29: Major diseases and pests of blackberries 30: Major diseases and pests of bilberries 31: Pesticides 32: Processing 33: General requirements for fruit for processing 34: Production of fruit juices 35: Production of dried fruit 36: Production of jellies and jams 37: Production of vinegar 38: Labelling of products 39: Marketing of organic products 40: Analysis of the situation 41: Plans - goals - measures 42: Marketing strategy 43: Marketing instruments 44: Efficiency review

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Book SynopsisNematodes are the most abundant and diversified group in the animal kingdom, with four out of five animals on earth being nematodes. Nematology was first recognised as an independent discipline during the early part of the century and since that time has made unparalleled advances to become an integral part of biological sciences. Written as two volumes, this title provides a broad overview of our current knowledge of nematology. The first volume addresses basic biology, while the second volume covers applied aspects of nematodes as parasites of plants, humans and other animals, or as disease vectors, and the control of pest nematodes. The contributors to this work include the world's leading authorities from Australia, Brazil, Canada, France, New Zealand, UK and USA. It will provide essential reading for researchers and students with an interest in nematology.Table of Contents1: A century of nematology. Ken R. Barker 2: Perspectives on nematology in the 21st century. John M. Webster 3: Developmental biology of nematodes, what we learn from Caenorhabditis elegans. Marie-Anne Félix 4: Nematode morphology, sensory structure and function. James G. Baldwin and Roland N. Perry 5: Nematode esophageal glands and plant parasitism. Richard S. Hussey and Eric L. Davis 6: Surface adhesion to nematodes and its consequences. Alan F. Bird 7: Nematode behavior and migrations through soil and host tissue. A. Forest Robinson 8: Background for nematode ecology in the 21st century. Gregor W. Yeates and Brian Boag 9: Marine nematode biodiversity. P. John. D. Lambshead 10: Population dynamics. Robert McSorley and Larry Duncan 11: Entomophilic nematode models for studying biodiversity and cospeciation. R. Giblin-Davis, Kelley Thomas, Kerrie Davies, and Gary Taylor 12: Cultivation of nematodes. Paul De Ley and Manuel Mundo-Ocampo

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Book SynopsisNematodes are the most abundant and diversified group in the animal kingdom, with four out of five animals on earth being nematodes. Nematology was first recognised as an independent discipline during the early part of the century and since that time has made unparalleled advances to become an integral part of biological sciences. Written as two volumes, this title provides a broad overview of our current knowledge of nematology. The first volume addresses basic biology, while this second volume covers applied aspects of nematodes as parasites of plants, humans and other animals, or as disease vectors, and the control of pest nematodes. The contributors to this work include the world's leading authorities from Australia, Brazil, Canada, France, New Zealand, UK and USA. It will provide essential reading for researchers and students with an interest in nematology.Table of Contents1: Plant diseases caused by nematodes, R H M Lopez, K Evans, Rothamsted Research, UK and J Bridge, CABI Bioscience, UK 2: Virus vectors, D J F Brown, Scottish Crop Research Institute, UK, J Zheng and X Zhou 3: Physiological interactions between nematodes and their host plants, H Melakeberhan, Michigan State University, USA 4: Insect Parasitic Nematodes, K B Nguyen and G C Smart, Jr., University of Florida, USA 5: Resistance to plant-parasitic nematodes, J L Starr, Texas A & M University, USA and P A Roberts 6: Crop rotation and other cultural practices, J M Halbrendt, Fruit Research and Ext. Center, Pennsylvania, USA and J A LaMondia, The Connecticut Ag. Expt. Station, Connecticut 7: Use of antagonistic plants and natural products, S Ferraz, Universidad Federal de Vicosa, Brazil 8: Biological control with fungal antagonists, S Chen and D W Dickson 9: Biological control of nematodes by bacterial antagonists, Z X Chen and D W Dickson 10: Biological control of insects and other invertebrates with nematodes, H Kaya and A Koppenhofer, University of California - Davis, USA 11: Cost-benefits of nematode management through regulatory programs, P S Lehman, Florida Department of Agriculture and Consumer Services, Gainesville, Florida, USA 12: Nematicides: Past and present uses, J R Rich, University of Florida, Quincy, USA, R A Dunn and J W Noling 13: Irradiation effects on plant-parasitic nematodes, D W Dickson

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Book SynopsisThere is a growing awareness that an understanding of international plant health agreements and protocol is essential in the increasingly free-trade environment of today, and that administrative methods of plant pest control are important in crop production. However, there has been no recent book, which introduces students and practitioners to the subject of plant health and quarantine. This book fills this gap.Table of Contents1: Introduction to plant health and quarantine 2: Early history of plant health control measures 3: International phytosanitary controls 4: The European Union plant health regime 5: Operation of national plant protection organisations 6: Imports and exports 7: Eradication and containment 8: Principles of certification and marketing schemes 9: International certification and marketing schemes 10: Indexing and diagnosis in plant health 11: Pest risk analysis 12: Hygiene and precautionary measures 13: Appendix I 14: The regional plant protection organisations 15: Appendix II 16: Convention concerning the measures to be taken against Phylloxera vastatrix, 1878 17: Appendix III 18: International controls on the use of plant pests as offensive agents

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Book SynopsisThis is the first scholarly reference work to cover all the major scientific themes and facets of the subject of seeds. It outlines the latest fundamental biological knowledge about seeds, together with the principles of agricultural seed processing, storage and sowing, the food and industrial uses of seeds, and the roles of seeds in history, economies and cultures. With contributions from 110 expert authors worldwide, the editors have created 560 authoritative articles, illustrated with plentiful tables, figures, black-and-white and colour photographs, suggested further reading matter and 670 supplementary definitions. The contents are alphabetically arranged and cross-referenced to connect related entries.Table of Contents1: Preface 2: Alphabetical Entries 3: Crop Atlas Appendix 4: Index of Species

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Book SynopsisWestern Corn Rootworm, Diabrotica virgifera virgifera LeConte, has been a major economic pest of maize in the Americas for many years. However, since the early 1990's it has become an increasing threat to crops in Europe and is expected to spread to all maize growing areas of the continent. This book provides a comprehensive review of current knowledge of the biology and ecology of this insect pest and how it might be managed in order to limit its damage as it spreads into new agroecological areas. Cultural, biotechnical, and biological control measures are addressed, as are ecological baseline data such as population dynamics, economic thresholds and aspects of its behaviour. The book also examines the potential of plant protection techniques currently used in North America to be applied in Europe.Table of Contents1: Invasive Alien Species - a Threat to Global Biodiversity and Opportunities to Prevent and Manage Them 2: Monitoring of Western Corn Rootworm (Diabrotica virgifera virgifera LeConte) in Europe 1992-2003 3: A Synopsis of the Nutritional Ecology of Larvae and Adults of Diabrotica virgifera virgifera (LeConte)in the New and Old World- Nouvelle Cuisine for the Invasive Maize Pest Diabrotica virgifera virgifera in Europe? 4: Western Corn Rootworm, Cucurbits and Curcurbitacins 5: Natural Mortality Factors Acting on Western Corn Rootworm Populations: a Comparison between the United States and Central Europe. 6: Movement, Dispersal and Behaviour of Western Corn Rootworrm Adults in Rotated Maize and Soyabean Fields. 7: Within-field Spatial Variation of Northern Corn Rootworm Distributions 8: Heterogeneous Landscapes and Variable Behaviour: Modelling Rootworm Evolution and Geographic Spread 9: Sampling Devices and Decision Rule Development for Western Corn Rootworm (Diabrotica virgifera virgifera LeConte) Adults in Soybean to Predict Subsequent Damage to Maize in Indiana 10: Western Corn Rootworm (Diabrotica virgifera virgifera LeConte) and the Crop Rotation Systems in Europe 11: Application of the Areawide Concept Using Semiochemical­ based Insecticide Baits for Managing the Western Corn Rootworm (Diabrotica virgifera virgifera LeConte) Variant in the Eastern Midwest 12: Genetically Enhanced Maize as a Potential Management Option for Corn Rootworm: YieldGard® Rootworm Maize Case Study 13: Is Classical Biological Control against Western Corn Rootworm in Europe a Potential Sustainable Management Strategy? 14: Maize Growing, Maize High-risk Areas and Potential Yield Losses due to Western Corn Rootworm (Diabrotica virgifera virgifera LeConte) Damage in Selected European Countries

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Book SynopsisThe conservation of genetic resources is vital to the maintenance of biodiversity and to the world's ability to feed its growing population. There are now more than a thousand genebanks worldwide involved in the ex situ (meaning away from the source) storage of particular classes of crops. Since the 1970s, the eleven genebanks maintained by the centres of the Consultative Group on International Agricultural Research (CGIAR) have become pivotal to the global conservation effort. However, key policy and management issues usually with economic dimensions have largely been overlooked.This provided the impetus for a series of detailed economic studies, led by IFPRI, in collaboration with five CGIAR centres: CIAT (based in Colombia), CIMMYT (Mexico), ICARDA (Syria), ICRISAT (India) and IRRI (Philippines). This book reports these studies and discusses their wider implications.Table of Contents1: Introduction, B Koo, P G Pardey, and B D Wright 2: The Economics of Genebank Costing, B Koo, P G Pardey, and B D Wright 3: CIMMYT Genebank, P G Pardey, B Koo, M Eric Van Dusen, University of California, Davis, USA, B Skovmand and S Taba, Centro Internacional de Mejoramiento de Maiz y Trigo (CIMMYT), Mexico, and B D Wright 4: ICARDA Genebank, B Koo, P G Pardey, J Valkoun, International Center for Agricultural Research in the Dry Areas (ICARDA), Syria, and B D Wright 5: ICRISAT Genebank, B Koo, P G Pardey, N Kameswara Rao and P J Bramel, International Crops Research Institute for the Semi-Arid Tropics (ICRISAT), India 6: IRRI Genebank, B Koo, P G Pardey, and M T Jackson, International Rice Research Institute (IRRI), Phillipines 7: CIAT Genebank, B Koo, P G Pardey, and D Debouck, Centro International de Agricultura Tropical (CIAT), Columbia 8: Policy and Management Implications, B Koo, P G Pardey, and B D Wright

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Book SynopsisInternational forums have identified the need for comprehensive, transparent, scientific methods, for the pre-release testing and post-release monitoring of transgenic plants to ensure environmental safety. There is also wide recognition that the regulatory and scientific capacity for conducting these types of assessments needs to be strengthened. In response to these requirements, a GMO Guidelines Project was established - under the aegis of the International Organization for Biological Control - to develop biosafety testing guidelines for transgenic plants. This book is one of the first outputs from this project. The book aims, using the case study of Bt maize, to detail generic approaches to the evaluation of environmental impact of GM technologies. This book focuses on transgenic maize in Kenya. This maize includes genetic material derived from the bacterium, Bacillus thuringiensis (Bt), which naturally produces proteins that are toxic to some insects. The book explores bothTable of Contents1: Bt Maize, Risk Assessment and the Kenya Case Study, 2: The Maize Agricultural Context in Kenya, 3: Problem Formulation and Options Assessment (PFOA) for Genetically Modified Organisms: The Kenya Case Study, 4: Transgene Locus Structure and Expression of Bt Maize, 5: Biodiversity and Non-Target Impacts: a Case Study of Bt Maize in Kenya, 6: Gene Flow and its Consequences: a Case Study of Bt Maize in Kenya, 7: Resistance Risks and Management Associated with Bt Maize in Kenya, 8: Risk Assessment of Bt Maize in Kenya: Synthesis and Recommendations,

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Book Synopsis* State-of-the-art reviews on topics in horticultural science and technology covering both basic and applied research. * Topics covered include the horticulture of fruits, vegetables, nut crops, and ornamentals.Table of ContentsDedication: Kim E. Hummer (Joseph Postman) 1. Spices: Frankincense, Myrrh, and Balm of Gilead: Ancient Spices of Southern Arabia and Judea (Shimshon Ben-Yehoshua, Carole Borowitz, and Lumír Ondøej Hanus) 2. Ginger: Botany and Horticulture (V. A. Parthasarathy, V. Srinivasan, R. R. Nair, T. John Zachariah, A. Kumar, and D. Prasath) 3. Annatto: Botany and Horticulture (Freddy Leal and Claret Michelangeli de Clavijo) 4. Mediterranean Stone Pine: Botany and Horticulture (Sven Mutke, Rafael Calama, Santiago C. González-Martínez, Gregorio Montero, F. Javier Gordo, David Bono, and Luis Gil) 5. Pointed Gourd: Botany and Horticulture (Sanjeev Kumar and B.D. Singh) 6. The Physiology and Functions of Fruit Pigments: An Ecological and Horticultural Perspective (Willem J. Steyn) 7. Advances in the Biology and Management of Monosporascus Vine Decline and Wilt of Melons and other Cucurbits (Roni Cohen, Shimon Pivonia, Kevin M. Crosby, and Ray D. Martyn) 8. Ornamental Grasses (Mary Hockenberry Meyer)

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Book SynopsisPlant Breeding Reviews presents state-of-the-art reviews on plant genetics and the breeding of all types of crops by both traditional means and molecular methods. Many of the crops widely grown today stem from a very narrow genetic base; understanding and preserving crop genetic resources is vital to the security of food systems worldwide. The emphasis of the series is on methodology, a fundamental understanding of crop genetics, and applications to major crops.The series issponsored by the American Society for Horticultural Science andappears in the form of one or two volumes per year.Table of ContentsContributors ix 1. Dedication: Molly M. Jahn Plant Breeder and Geneticist 1 I. L. Goldman I. Biographical Sketch 1 II. Research Program 5 III. Teaching 7 IV. Administration 7 V. Awards and Recognition 9 VI. The Woman 9 Literature Cited 10 Selected Publications of Molly M. Jahn 10 Germplasm Releases and Patents 16 2. History, Evolution, and Domestication of Brassica Crops 19 Shyam Prakash, Xiao-Ming Wu, and S. R. Bhat I. Introduction 21 II. Archetypes and Evolution of Basic Genomes and Derived Allopolyploids 25 III. Ethnobotany, Origin, and Domestication 36 IV. Concluding Remarks 67 Acknowledgments 70 Literature Cited 71 3. Melon Landraces of India: Contributions and Importance 85 Narinder P. S. Dhillon_, Antonio J. Monforte, Michel Pitrat, Sudhakar Pandey, Praveen Kumar Singh, Kathleen R. Reitsma, Jordi Garcia-Mas, Abhishek Sharma, and James D. McCreight I. Introduction 88 II. First Contribution of Indian Melon Germplasm to the U.S. Melon Breeding Programs 90 III. Useful Traits from Indian Melons 92 IV. Genetic Diversity 120 V. Melon Breeding 123 VI. Future Role of Indian Melon Germplasm and Conclusions 130 Acknowledgments 133 Literature Cited 133 4. Transgenic Vegetable Crops: Progress, Potentials, and Prospects 151 João Silva Dias and Rodomiro Ortiz I. World Vegetable Production 153 II. Case for Transgenic Vegetables 154 III. Case Studies 164 IV. GM Vegetables and Integrated Pest Management 218 V. Outlook 221 Literature Cited 224 5. Millets: Genetic and Genomic Resources 247 Sangam Dwivedi, Hari Upadhyaya, Senapathy Senthilvel, Charles Hash, Kenji Fukunaga, Xiamin Diao, Dipak Santra, David Baltensperger, and Manoj Prasad I. Introduction 251 II. Nutritional Quality and Food, Feed, Medicinal, and Other Uses 269 III. Domestication, Phylogenetic, and Genomic Relationships 277 IV. Assessing Patterns of Diversity in Germplasm Collections 284 V. Identifying Germplasm with Beneficial Traits 300 VI. Genomic Resources 316 VII. Enhancing Use of Germplasm in Cultivar Development 321 VIII. From Trait Genetics to Association Mapping to Cultivar Development Using Genomics 332 IX. Conclusions and Future Prospects 344 Acknowledgments 347 Literature Cited 347 Subject Index 377 Cumulative Subject Index 379 Cumulative Contributor Index 401 ??

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Book SynopsisTemperature and Plant Development provides a detailed analysis of the role of temperature fluctuations and stressors in plant development. Renowned experts in plant biology outline plant adaptation to high and low temperature stress, whole plant psychological adaptations, and temperature-regulated gene networks.Table of ContentsContributors xi Preface xiii 1 Temperature sensing in plants 1 Steven Penfield and Dana MacGregor 1.1 Introduction 1 1.2 Passive and active temperature responses in plants 1 1.3 Temperature sensing during transcriptional regulation 3 1.4 Sensing cold: A role for plasma membrane calcium channels in plants 8 1.5 A role for membrane fluidity as an upstream temperature sensor? 11 1.6 Temperature sensing by proteins 12 1.7 Summary 14 2 Plant acclimation and adaptation to cold environments 19 Bob Baxter 2.1 Introduction 19 2.2 Chilling and freezing injury 20 2.3 Freezing avoidance and tolerance at the structural and physiological level 21 2.4 Freezing tolerance 26 2.5 Cold deacclimation (dehardening) and reacclimation (rehardening) 32 2.6 Spatial and temporal considerations of plant responses to low temperature 34 2.7 The survival of cold and freezing stress in a changing climate 38 2.8 Plant cold acclimation and adaptation in an agricultural context 42 2.9 Summary 42 3 Plant acclimation and adaptation to warm environments 49 Martijn van Zanten, Ralph Bours, Thijs L. Pons, and Marcel C.G. Proveniers 3.1 Introduction 49 3.2 Implications of high temperature for agriculture and natural ecosystems 51 3.3 Temperature perception and signaling pathways 52 3.4 Photosynthesis 53 3.5 Respiration and carbon balance 57 3.6 Growth and allocation of biomass 58 3.7 Architectural changes in response to high temperature 58 3.8 Hormonal regulation of thermotolerance 62 3.9 Functional implications of plant architectural changes to high temperature 63 3.10 Interactions between drought and high temperature 64 3.11 Carbohydrate status control of plant acclimation to high temperature 65 3.12 Thermoperiodic effects on plant growth and architecture 66 3.13 High-temperature effects on the floral transition 68 4 Vernalization: Competence to flower provided by winter 79 Dong-Hwan Kim and Sibum Sung 4.1 Introduction 79 4.2 Vernalization requirement in Arabidopsis 80 4.3 The molecular mechanism of vernalization 84 4.4 Resetting of FLC repression during meiosis 88 4.5 Vernalization in other plant species 89 4.6 Concluding remarks 91 5 Temperature and light signal integration 97 Harriet G. McWatters, Gabriela Toledo-Ortiz, and Karen J. Halliday 5.1 Introduction 97 5.2 Convergence points for light and temperature sensing 101 5.3 Phytochrome-Interacting Factors as signal integrators 102 5.4 ELONGATED HYPOCOTYL 5 (HY5): A cool operator 105 5.5 Light and temperature converge at the circadian oscillator 107 5.6 Photoperiodic and thermal control of flowering 113 5.7 Light-dependent circadian gating of cold-acclimation responses 115 5.8 Temperature and light regulation of cell membrane fatty acid composition 117 5.9 Concluding thoughts: Implications for a changing future 118 6 Temperature and the circadian clock 131 Kathleen Greenham and C. Robertson McClung 6.1 Introduction 131 6.2 Temperature compensation 136 6.3 Temperature entrainment 142 6.4 Cold tolerance 146 6.5 Splicing 150 6.6 Concluding remarks 151 7 Temperature and plant immunity 163 Jian Hua 7.1 Introduction 163 7.2 Plant immunity 164 7.3 Temperature effects on plant disease resistance 167 7.4 The molecular basis for temperature sensitivity in plant immunity 170 7.5 Evolution of the temperature sensitivity of immunity 174 7.6 Concluding remarks 176 8 Temperature, climate change, and global food security 181 Robert J. Redden, Jerry L. Hatfield, P.V. Vara Prasad, Andreas W. Ebert, Shyam S. Yadav, and Garry J. O’Leary 8.1 Introduction 181 8.2 Climate change on a global basis 181 8.3 The impact of temperature on crop water relations 183 8.4 The influence of high temperature on crop physiology and yield processes 186 8.5 The interaction of climate change factors on crop development 188 8.6 The impact of global climate change on food quality and plant nutrient demand 190 8.7 Breeding high-temperature stress tolerance using crop wild relatives 190 8.8 Global food production and food security 191 8.9 Crop nutritional content 194 8.10 Discussion 196 8.11 Conclusions 197 Index 203 Color plate section is located between pages 130 and 131.

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Book SynopsisThe development of recombinant DNA methods has changed the face of the food industry over the last 50 years. Crops which have been genetically modified are being cultivated in more and more countries and this process is likely to accelerate as desirable traits are identified and transferred to appropriate organisms, and they are cleared by the regulatory authorities. However, the technique has its critics who claim that modification of the genome of the plant (or animal) in this way may pose unknown and unacceptable risks to the human consumer. Genetic Modification and Food Quality: A Down to Earth Analysis is the first comprehensive text on how GM production methods influence the quality of foods and feeds, based on a complete and unbiased assessment of the scientific findings. It presents a balanced analysis of the benefits and drawbacks of gene-modified food sources in the human diet. Chapters approach the topic with regard to different food types such as cereal grains, oilseed cropTrade Review"Genetic Modification and Food Quality: A Down to Earth Analysis is the first comprehensive text on how GM production methods influence the quality of foods and feeds, based on a complete and unbiased assessment of the scientific findings. It presents a balanced analysis of the benefits and drawbacks of gene-modified food sources in the human diet." (South African Food Science and Technology July 2017)Table of Contents1 Introduction 1 2 International regulations 4 3 Microorganisms 20 4 Cereals 35 5 Oilseed crops 81 6 Fruits and vegetables 141 7 Fish and other animals 174 8 Animal products 181 9 Overall assessment of the safety of GM foods and feeds 200 10 Overall assessment of the nutritional value of GM foods and feeds 211 11 Addressing consumer issues 250 12 Overall conclusions 262 Index 271

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Book SynopsisA review of various types of whole grains, the bioactives present within them, and their health-promoting effects As rates of obesity and other chronic conditions continue to rise, so too does the need for clear and accurate information on the connections between diet and disease, particularly regarding the cereal grains that dominate the Western diet. In this volume, editors Jodee Johnson and Taylor Wallace assemble a panel of leading experts to address this issue. The result is a comprehensive examination of the cereal and pseudo-cereal grains and their most important bioactive compounds. Not only does this volume offer summaries of existing research, it also places these findings within the larger context of health promotion and disease prevention. This includes frank discussions on the limitations of existing studies, as well as current gaps in research for those who want to offer evidence-based recommendations to their patients. Topics addressed include:Table of ContentsList of Contributors xv Part I Introduction 1 1 Introduction to Whole Grains and Human Health 3Jodee Johnson and Taylor C. Wallace 1.1 History of Whole Grains 4 1.2 Who Consumes Whole Grains? 5 1.3 What are Whole Grains? 5 1.4 Components of Whole Grains 6 1.5 Whole Grain Bioactives 6 1.6 Health-Promoting Effects of Whole Grains 7 1.7 Conclusion 13 References 13 Part II Whole Grains, Whole Food Nutrition 19 2 Wheat 21Daniel D. Gallaher and James A. Anderson 2.1 Introduction 21 2.2 History of the Grain 21 2.3 Types 22 2.4 Nutritional Composition 25 2.5 Health Effects on Chronic Diseases 30 2.6 Conclusion 35 References 36 3 Oats 45Yao Tang, Aaron Yerke and Shengmin Sang 3.1 Introduction 45 3.2 Nutritional Composition 47 3.3 Health Effects in Chronic Diseases 52 3.4 Conclusion 55 References 55 4 Rice 63Nora Jean Nealon and Elizabeth P. Ryan 4.1 Introduction 63 4.2 History of Whole Grain Rice 63 4.3 Variety in Whole Grain Rice Quality and Preferences 64 4.4 Nutritional Composition and Bioactive Compounds in Whole Grain Rice 64 4.5 Whole Grain Rice Consumption and Prevention Against Chronic Disease 77 4.6 Whole Grain Rice Consumption and Protection Against Gut Pathogens 81 4.7 Conclusion 82 Acknowledgments 83 References 83 5 Corn 113Siyuan Sheng, Tong Li and Rui Hai Liu 5.1 Introduction 113 5.2 Macro-and Micronutrients in Corn 114 5.3 Corn Phytochemicals 114 5.4 Health Benefits 124 5.5 Conclusion 128 References 128 6 Barley 135Clarence W. (Walt) Newman, Rosemary K. Newman and Christine E. Fastnaught 6.1 Introduction 135 6.2 The Beginning 135 6.3 The Whole Grain Barley Kernel 137 6.4 Health Effects of Bioactive Compounds in Barley on Chronic Diseases 149 6.5 Conclusion 156 References 156 7 Rye 169Laila Meija and Indrikis Krams 7.1 Introduction 169 7.2 Types 171 7.3 Consumption 171 7.4 Epidemiological Studies of Rye Intake 171 7.5 Rye Products 172 7.6 Nutritional Composition 177 7.7 Phytochemicals 178 7.8 Rye Fiber 178 7.9 Health Effects on Chronic Diseases 186 7.10 Gut Health 191 7.11 Cancer 192 7.12 Conclusion 198 References 198 Part III Pseudo Cereal Grains, Whole Food Nutrition 209 8 Amaranth 211Aída Jimena Velarde-Salcedo, Esaú Bojórquez-Velázquez and Ana Paulina Barba de la Rosa 8.1 Introduction 211 8.2 History of Amaranth 212 8.3 Amaranth Genetic Diversity 213 8.4 Amaranth Plant Physiology 215 8.5 Amaranth Seed Morphology 216 8.6 Amaranth Seed Chemical Composition and Nutritional Properties 217 8.7 Phytochemical Compounds in Amaranth Seeds 223 8.8 Amaranth Seed Storage Proteins 224 8.9 Health Effects of Amaranth Grain 226 8.10 Conclusion 240 References 240 9 Buckwheat 251Juan Antonio Giménez Bastida, José Moisés Laparra Llopis and Henryk Zielinski 9.1 Introduction 251 9.2 History of the Grain 251 9.3 Nutritional Composition of Buckwheat 253 9.4 Metabolism and Bioavailability 254 9.5 Health Effects on Chronic Diseases 255 9.6 Conclusion 260 Acknowledgments 260 References 260 10 Quinoa 269Beenu Tanwar, Ankit Goyal, Syed Irshaan, Vikas Kumar, Manvesh Kumar Sihag, Ami Patel and Intelli Kaur 10.1 Introduction 269 10.2 History of the Quinoa Grain 270 10.3 Types of Quinoa 270 10.4 Nutritional Composition 271 10.5 Phytochemicals/Bioactives and Antinutritional Factors 277 10.6 Health Benefits 287 10.7 Food Applications 294 10.8 Future Prospects 294 10.9 Conclusion 295 References 295 Part IV Health-Promoting Properties of Whole Grain Bioactive Compounds 307 11 Avenanthramides 309Tianou Zhang and Li Li Ji 11.1 Introduction 309 11.2 Presence in Whole Grains 309 11.3 Chemical Structure and Biosynthesis 310 11.4 Effects of Processing 311 11.5 Absorption, Distribution, Metabolism, and Excretion 314 11.6 Health Benefits 320 11.7 Conclusions and Future Research 330 References 331 12 𝛃-Glucans 339Susan Tosh and S. Shea Miller 12.1 Introduction 339 12.2 Presence and Distribution in Whole Grains 340 12.3 Chemistry 342 12.4 Mechanisms of Action 344 12.5 Effects of Processing 348 12.6 Conclusion 350 References 351 13 Phenolic Acids 357C-Y. Oliver Chen, Sérgio M. Costa and Klinsmann Carolo 13.1 Introduction 357 13.2 Presence of Phenolic Acids in Whole Grain 358 13.3 Factors Affecting Phenolic Acid Content in Grains 363 13.4 Bioaccessibility and Bioavailability of Grain Phenolic Acids 365 13.5 Health Benefits of Grain Phenolic Acids 366 13.6 Conclusion 370 References 371 14 Carotenoids 383Elizabeth J. Johnson 14.1 Introduction 383 14.2 Chemistry 384 14.3 Presence in Whole Grains 384 14.4 Dietary Databases 387 14.5 Bioavailability 387 14.6 Effect of Processing, Storage, and Environment 388 14.7 Conclusion 389 References 389 15 Alkylresorcinols 393Alastair B. Ross 15.1 Introduction 393 15.2 Chemistry and Nomenclature 393 15.3 Presence of Alkylresorcinols in Cereals 394 15.4 Effect of Food Processing on Alkylresorcinols 394 15.5 Measuring Alkylresorcinols 396 15.6 Intake of Alkylresorcinols 397 15.7 Bioavailability and Pharmacokinetics of Alkylresorcinols 398 15.8 Biological Effects of Alkylresorcinols 398 15.9 Mechanisms of Action 399 15.10 Use of Alkylresorcinols and Their Metabolites as Biomarkers of Whole Grain Intake 400 15.11 Conclusion 402 References 402 16 Lignans 407Iman Zarei and Elizabeth P. Ryan 16.1 Introduction 407 16.2 Presence in Whole Grains 408 16.3 Chemistry 408 16.4 Metabolism of Lignans by Human Gut Microbiota and Bioavailability 410 16.5 Biological Activities 413 16.6 Impact of Agronomic Factors on Lignan Content in Foods 414 16.7 Effect of Processing 414 16.8 Safety 415 16.9 Conclusion 415 Acknowledgments 420 References 420 17 Phytosterols 427Dan Zhu, and Laura Nyström 17.1 Introduction 427 17.2 Chemistry 427 17.3 Presence in Whole Grains 431 17.4 Bioaccessibility and Bioavailability 442 17.5 Mechanisms of Action 446 17.6 Effect of Processing 451 17.7 Conclusion 454 References 454 18 Phytic Acid and Phytase Enzyme 467Vikas Kumar, Amit K. Sinha and Kimia Kajbaf 18.1 Introduction 467 18.2 Food Sources of Phytic Acid 468 18.3 Phytase 469 18.4 Classification of Phytase 474 18.5 Factors Influencing Phytase Bioefficacy 474 18.6 Source of Phytase 476 18.7 Beneficial Health Effects of Phytate 476 18.8 Conclusion 478 References 478 Index 485

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Book SynopsisThe only single-source reference on the science of olives and olive oil nutrition and health benefits Olives and Olive Oil as Functional Foods is the first comprehensive reference on the science of olives and olive oil. While the main focus of the book is on the fruit's renowned health-sustaining properties, it also provides an in-depth coverage of a wide range of topics of vital concern to producers and researchers, including post-harvest handling, packaging, analysis, sensory evaluation, authentication, waste product utilization, global markets, and much more. People have been cultivating olives for more than six millennia, and olives and olive oil have been celebrated in songs and legends for their life-sustaining properties since antiquity. However, it is only within the last several decades that the unique health benefits of their consumption have become the focus of concerted scientific studies. It is now known that olives and olive oilcontain an abTable of ContentsList of Contributors xiii Preface xix 1 Olive tree history and evolution 1 Giorgos Kostelenos and Apostolos Kiritsakis 1.1 Introduction 1 1.2 The olive culture in the Mediterranean region 1 1.3 Evolution of the olive tree from a botanical point of view 3 1.4 A different approach 6 1.5 Conclusion 10 References 11 2 Botanical characteristics of olive trees: cultivation and growth conditions – defense mechanisms to various stressors and effects on olive growth and functional compounds 13 Eleni Tsantili, Evangelos Evangelou, and Apostolos Kiritsakis 2.1 Introduction 13 2.2 Botanical characteristics 15 2.3 Cultivation and growth conditions 18 2.4 Defense mechanisms against various stresses 22 2.5 Factors affecting olive growth and functional compounds 24 2.6 Conclusion 27 References 27 3 Conventional and organic cultivation and their effect on the functional composition of olive oil 35 Nikolaos Volakakis, Emmanouil Kabourakis, and Carlo Leifert 3.1 Introduction 35 3.2 Productivity 36 3.3 Environmental impact 36 3.4 Pesticide residues 37 3.5 Oil composition and quality 37 3.6 Conclusion 40 References 40 4 The influence of growing region and cultivar on olives and olive oil characteristics and on their functional constituents 45 Joan Tous 4.1 Introduction 45 4.2 Overview of olive orchards in some world crop areas 45 4.3 Global olive oil cultivars 53 4.4 Olive oil composition affected by genetic and environmental factors 69 4.5 Conclusion 76 Acknowledgments 76 References 76 5 Olive fruit and olive oil composition and their functional compounds 81 Fatima Paiva-Martins and Apostolos Kiritsakis 5.1 Introduction 81 5.2 The olive fruit 81 5.3 Description of olive fruit and olive oil constituents 82 5.4 Olive oil 83 5.5 Pigments 88 5.6 Phenols 89 5.7 Hydrocarbons 97 5.8 Triterpenoids 98 5.9 Tocopherols 99 5.10 Aliphatic alcohols and waxes 100 5.11 Sterols 100 5.12 Flavor compounds 103 5.13 Conclusion 104 Acknowledgments 105 References 105 6 Mechanical harvesting of olives 117 Sergio Castro-Garcia and Louise Ferguson 6.1 Introduction 117 6.2 Fruit removal from the tree 117 6.3 Collection, cleaning, and transport of fallen fruits 120 6.4 Continuous harvesters 123 6.5 Effects on oil and fruit quality 124 6.6 Conclusion 124 References 124 7 Olive fruit harvest and processing and their effects on oil functional compounds 127 Apostolos Kiritsakis and Nick Sakellaropoulos 7.1 Introduction 127 7.2 Harvest time 127 7.3 Harvest techniques 129 7.4 Olive storage and transportation to the olive oil mill 130 7.5 Processing steps 131 7.6 Pressure process 136 7.7 Centrifugation process 137 7.8 Selective filtration (Sinolea) process 138 7.9 Processing systems 139 7.10 Olive fruit processing by-products and their significance 140 7.11 The effect of enzymes in olive fruit processing and oil composition 141 7.12 Effect of processing systems on olive oil quality and functional properties 141 7.13 Conclusion 142 References 142 8 Application of HACCP and traceability in olive oil mills and packaging units and their effect on quality and functionality 147 Athanasia M. Goula, Konstantinos Kiritsakis, and Apostolos Kiritsakis 8.1 Introduction 147 8.2 The basic HACCP benefits and rules 147 8.3 Description and analysis of the HACCP program in the olive oil mill 149 8.4 Application of the HACCP program in the packaging unit 159 8.5 The context of traceability 162 8.6 Traceability of olive oil 163 8.7 Legislation for olive oil traceability 164 8.8 Compositional markers of traceability 166 8.9 DNA-based markers of traceability 169 8.10 Sensory profile markers of traceability 170 8.11 Conclusion 171 References 172 9 Integrated olive mill waste (OMW) processing toward complete by-product recovery of functional components 177 Athanasia M. Goula and Dimitrios Gerasopoulos 9.1 Introduction 177 9.2 Characterization of olive mill waste 179 9.3 Current technologies for olive mill waste treatment 184 9.4 Recovery of functional components from olive mill waste 187 9.5 Integral recovery and revalorization of olive mill waste 194 9.6 Conclusion 197 References 197 10 Olive oil quality and its relation to the functional bioactives and their properties 205 Apostolos Kiritsakis and Fereidoon Shahidi 10.1 Introduction 205 10.2 Hydrolysis (lipolysis) 205 10.3 Oxidation 206 10.4 Prevention of olive oil autoxidation 208 10.5 Photooxidation 209 10.6 Olive oil quality evaluation with methods other than the official 211 10.7 Behavior of olive oil during frying process 212 10.8 Off flavors of olive oil 213 10.9 Factors affecting the quality of olive oil and its functional activity 214 10.10 Effect of storage on quality and functional constituents of olive oil 216 10.11 Conclusion 216 References 216 11 Optical nondestructive UV-Vis-NIR-MIR spectroscopic tools and chemometrics in the monitoring of olive oil functional compounds 221 Vasiliki Lagouri, Vasiliki Manti, and Thanasis Gimisis 11.1 Introduction: functional compounds in olive oil 221 11.2 An introduction to UV-Vis-NIR-MIR spectroscopy in olive oil analysis 222 11.3 Spectroscopic regions with interest for olive oil analysis 222 11.4 The basics of chemometrics 227 11.5 Spectral preprocessing methods 228 11.6 UV-Vis-NIR-MIR spectroscopy and chemometrics in monitoring olive oil functional compounds 229 11.7 UV-Vis-NIR-MIR spectroscopy and chemometrics in monitoring olive oil oxidation 237 11.8 FTIR spectroscopy and chemometrics in monitoring olive oil functional compounds and antioxidant activity 240 11.9 The use of UV-Vis-NIR-MIR spectroscopy in olive oil industry and trade 241 11.10 Conclusion 244 Acknowledgments 244 References 244 12 Oxidative stability and the role of minor and functional components of olive oil 249 Giuseppe Fregapane and María Desamparados Salvador 12.1 Introduction 249 12.2 Olive oil oxidative stability 249 12.3 Accelerated oxidative assays and shelf-life prediction 254 12.4 Stability of olive oil components: fatty acids and minor components 256 12.5 Antioxidant capacity of olive oil functional components 260 12.6 Conclusion 261 References 262 13 Chemical and sensory changes in olive oil during deep frying 267 George Siragakis and Dafni Karamanavi 13.1 Introduction 267 13.2 Alterations of chemical characteristics in frying olive oil 268 13.3 Oxidation of olive oil during frying 270 13.4 Methods for determination of polar compounds and evaluation of the quality of frying olive oil 270 13.5 Evaluation of the quality of frying olive oil 272 13.6 Prediction of oxidative stability under heating conditions 272 13.7 Impact of deep frying on olive oil compared to other oils 273 13.8 Conclusion 274 References 274 14 Olive oil packaging: recent developments 279 Michael G. Kontominas 14.1 Introduction 279 14.2 Migration aspects during packaging 279 14.3 Flavor scalping 280 14.4 Effect of packaging materials on olive oil quality 280 14.5 Conclusions 291 References 292 15 Table olives: processing, nutritional, and health implications 295 Stanley George Kailis and Apostolos Kiritsakis 15.1 Introduction 295 15.2 Olive maturation stages for table olive processing 295 15.3 Olive cultivars suitable for table olive processing 298 15.4 Factors affecting raw olive fruit for table olive processing 299 15.5 Table olive processing 301 15.6 Nutritional, health, and safety aspects of table olives 311 15.7 Quality and safety aspects relating to table olives 315 15.8 Antibiotic aspects of olive polyphenols 320 15.9 Probiotic capability of table olive products 320 15.10 Conclusion 321 References 321 16 Greek-style table olives and their functional value 325 Athena Grounta, Chrysoula C. Tassou, and Efstathios Z. Panagou 16.1 Introduction 325 16.2 Table olive processing in Greece 326 16.3 Functional value of Greek table olives 330 16.4 Conclusion 338 References 338 17 Food hazards and quality control in table olive processing with a special reference to functional compounds 343 Mohamed Rahmani 17.1 Introduction 343 17.2 Table olive processing techniques 345 17.3 New trends in table olive processing and quality control, with a special reference to functional products 347 17.4 Food safety requirements for table olives 348 17.5 Conclusion 350 References 351 18 Improving the quality of processed olives: acrylamide in Californian table olives 353 Charoenprasert Suthawan and Alyson E. Mitchell 18.1 Introduction 353 18.2 Acrylamide formation in food and potential adverse health effects 354 18.3 Regulation of acrylamide in food 359 18.4 Acrylamide levels in olive products 359 18.5 Effects of table olive processing methods on acrylamide formation 360 18.6 Methods to mitigate acrylamide levels in processed table olives 362 18.7 Conclusion 363 References 364 19 Antioxidants of olive oil, olive leaves, and their bioactivity 367 Apostolos Kiritsakis, Fereidoon Shahidi, and Charalampos Anousakis 19.1 Introduction 367 19.2 Synthetic antioxidants 368 19.3 Natural antioxidants 368 19.4 Phenols in table olives 370 19.5 Phenols and other constituents of olive leaves and other olive tree products 370 19.6 Extraction and activities of phenolics 372 19.7 Antioxidant and other properties of olive phenolics 376 19.8 Conclusion 378 References 378 20 Composition and analysis of functional components of olive leaves 383 Celia Rodríguez-Pérez, Rosa Quirantes-Piné, Jesús Lozano-Sánchez, Javier Menéndez, and Antonio Segura-Carretero 20.1 Introduction 383 20.2 Qualitative and quantitative analysis of olive leaves 383 20.3 Future prospects 395 Acknowledgments 397 References 397 21 Production of phenol-enriched olive oil 401 Kostas Kiritsakis and Dimitrios Gerasopoulos 21.1 Introduction 401 21.2 Olive oil phenolic compounds and their functional properties 401 21.3 Effect of the extraction process on olive oil functional compounds 402 21.4 Enhancement of olive oil’s antioxidant content 405 21.5 Conclusion 410 References 410 22 Olives and olive oil: a Mediterranean source of polyphenols 417 Anna Tresserra-Rimbau and Rosa M. Lamuela-Raventós 22.1 Introduction 417 22.2 Phenolic profile of olives and olive oils 417 22.3 Analytical approaches to characterize the phenolic profile of olives and olive oils 420 22.4 Stability of polyphenols: cooking effects 421 22.5 Health effects of olive and olive oil polyphenols 423 22.6 Conclusion 427 Acknowledgments 428 References 428 23 Bioactive components from olive oil as putative epigenetic modulators 435 Tea Bilusic 23.1 Introduction 435 23.2 Epigenetics as a new scientific challenge 435 23.3 Types of epigenetic modifications 437 23.4 Environmental factors and epigenetics (the role of the diet) 439 23.5 Epigenetics and human health 443 23.6 Epigenetics and aging 444 23.7 Olive oil components as dietary epigenetic modulators 446 23.8 Conclusion 449 References 449 24 Phenolic compounds of olives and olive oil and their bioavailability 457 Turkan Mutlu Keceli, Senem Kamiloglu, and Esra Capanoglu 24.1 Introduction 457 24.2 Phenolic compounds of olives and olive oil 458 24.3 Bioavailability of olive and olive oil phenolics 460 24.4 Conclusion 467 References 467 25 Antiatherogenic properties of olive oil glycolipids 471 Haralabos C. Karantonis 25.1 Introduction 471 25.2 The role of inflammation in the development of chronic diseases 471 25.3 The role of diet in inflammation 473 25.4 PAF and its metabolism as a searching tool for functional components with antiatherogenic activity 473 25.5 Functional components of olive oil with antiatherogenic properties 474 25.6 Conclusion 478 References 479 26 Nutritional and health aspects of olive oil and diseases 483 Elizabeth Lenart, Apostolos Kiritsakis, and Walter Willett 26.1 Introduction 483 26.2 Dietary lipids and cardiovascular disease 485 26.3 Fat intake and cancer 490 26.4 Obesity and dietary fat 494 26.5 Conclusion 495 References 496 27 Lipidomics and health: an added value to olive oil 505 Carla Ferreri and Chryssostomos Chatgilialoglu 27.1 Introduction 505 27.2 Lipidomics: an added value to olive oil 505 27.3 Membrane lipidomics and nutrilipidomics: natural oils for a healthy balance 506 27.4 Membrane as relevant site for lipidomic analysis 512 27.5 Conclusion and perspectives 517 Acknowledgments 517 References 517 28 Analysis of olive oil quality 521 Fereidoon Shahidi, Priyatharini Ambigaipalan, and Apostolos Kiritsakis 28.1 Introduction 521 28.2 Fatty acid composition and analysis 522 28.3 Measurement of oxidation 523 28.4 Determination of chlorophylls 529 28.5 Determination of phenols 530 28.6 Cold test 530 28.7 Determination of sterol content 530 28.8 Differential scanning calorimetry (DSC) of olive oil 531 28.9 Authentication and authenticity of olive oil 531 References 531 29 Detection of extra virgin olive oil adulteration 537 Hazem Jabeur, Akram Zribi, and Mohamed Bouaziz 29.1 Introduction 537 29.2 Parameters suitable for authenticity assessment of EVOO 538 29.3 Direct authenticity assessment of EVOO 546 29.4 Conclusion 549 Acknowledgments 550 References 550 30 Authentication of olive oil based on minor components 555 Styliani Christophoridou 30.1 Introduction 555 30.2 Sterols 555 30.3 Vitamin E – tocopherols 556 30.4 Phenols 558 30.5 Volatiles 559 30.6 Olive oil pigments 560 30.7 Conclusion 562 References 562 31 New analytical trends for the measurement of phenolic substances of olive oil and olives with significant biological and functional importance related to health claims 569 Eleni Melliou, Panagiotis Diamantakos, and Prokopios Magiatis 31.1 Introduction 569 31.2 Phenolic compounds of olive oil with special importance 569 31.3 Analysis of table olives 581 31.4 Conclusion 582 References 582 32 DNA fingerprinting as a novel tool for olive and olive oil authentication, traceability, and detection of functional compounds 587 Aliki Xanthopoulou, Ioannis Ganopoulos, Irene Bosmali, Athanasios Tsaftaris, and Panagiotis Madesis 32.1 Introduction 587 32.2 DNA-based fingerprinting 588 32.3 Omics approaches in olive and detection of functional compounds 595 References 596 33 Sensory properties and evaluation of virgin olive oils 603 Emmanuel Salivaras 33.1 Introduction 603 33.2 Description and review of methodology 603 33.3 Chemistry, functionality, and technology behind senses 612 33.4 Positive sensory attributes of virgin olive oil and its consumption 623 References 624 34 International standards and legislative issues concerning olive oil and table olives and the nutritional, functional, and health claims related 629 Stylianos Koulouris 34.1 Introduction 629 34.2 The international perspective 629 34.3 Legislative approach by various countries 632 34.4 The European Union perspective 636 34.5 Nutrition and health claims related to olive oils 638 34.6 Conclusion 644 References 644 35 The functional olive oil market: marketing prospects and opportunities 647 Konstantinos Mattas and Efthimia Tsakiridou 35.1 Introduction 647 35.2 The olive oil market 647 35.3 The influence of certifications of origin and production methods in olive oil 652 35.4 Case study: survey on consumption patterns, labeling, certification, and willingness to pay for olive oil 653 35.5 Promotional strategies 654 35.6 Conclusion 656 References 657 Future Research Needs 659 Index 661

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Book SynopsisCombines new findings on morphological aspects, the latest data on gene function in grasses, and the interaction of grasses with their habitats 45% of all arable land is covered by five grass crops: wheat, maize, rice, barley and sugar cane. This book demonstrates why crops and weeds are growing in characteristic environments today, and looks at how cropping practices may change in the future and how these changes will affect weed spectra. It explains the distribution of grasses and their role for mankind and summarizes our knowledge on grass genomes. Special emphasis is placed on the function of genes at defined developmental stages and in organs of grasses. The development of grasses is then described from the germination to fruit set with many unpublished examples. Grasses: Crops, Competitors and Ornamentals provides readers with a comparative description of selected grass organs (stem, root, leaf, inflorescence) and devotes several chapters to habitatTable of ContentsList of Contributors vii Foreword ix Acknowledgements xi Part I Introduction 1 1 Introduction 3Hansjoerg Kraehmer Part II Grass Genomics 11 2 Grass Sequencing Projects 13Todd Gaines 3 Grass Gene Sequences and Traits 25Hansjoerg Krähmer and Todd Gaines Part III Morphological and Physiological Characteristics of Grasses 29 4 Flower and Inflorescence 31Hansjoerg Kraehmer 5 Fertilisation and Fruit Development 89Hansjoerg Kraehmer and Peter Baur 6 Seedlings 165Hansjoerg Kraehmer 7 Leaf 195Hansjoerg Kraehmer and Peter Baur 8 Shoots 233Hansjoerg Kraehmer 9 Roots 435Hansjoerg Kraehmer 10 Growth Forms of Grasses 447Hansjoerg Kraehmer 11 Grass Surfaces 457Hansjoerg Kraehmer and Peter Baur Part IV Grasses as Crops 485 12 Arable Crops 487Hansjoerg Kraehmer 13 Bamboos 491Hansjoerg Kraehmer 14 Dominance of Grasses as Crops 495Hansjoerg Kraehmer Part V Grasses as Weeds 497 15 Dominance of Grasses as Weeds 499Hansjoerg Kraehmer and Carl Bell Part VI Grasses as Ornamentals 503 16 What Makes Grasses Attractive Ornamentals, and Where? 505Hansjoerg Kraehmer Part VII Natural Habitats of Grasses 517 17 Native Grasslands 519Carl Bell Part VIII Conclusions 549 18 Why Have Grasses Become So Successful? 551Hansjoerg Kraehmer Index 555

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Book SynopsisThe most up-to-date reference on phytomicrobiomes available today The Plant Microbiome in Sustainable Agriculture combines the most relevant and timely information available today in the fields of nutrient and food security. With a particular emphasis on current research progress and perspectives of future development in the area, The Plant Microbiome in Sustainable Agriculture is an invaluable reference for students and researchers in the field, as well as those with an interest in microbiome research and development. The book covers both terrestrial and crop associated microbiomes, unveiling the biological, biotechnological and technical aspects of research. Topics discussed include: Developing model plant microbiome systems for various agriculturally important cropsDefining core microbiomes and metagenomes in these model systemsDefining synthetic microbiomes for a sustainable increase in food production and quality The Plant Microbiome in Sustainable Agriculture is written to allTable of ContentsPreface vii List of Contributors ix About the Editors xiii 1 Plant Microbiome: Past, Present and Future 1Akhilendra Pratap Bharati, Ashutosh Kumar, Sunita Kumari, Anjney Sharma, Prem Lal Kashyap, Sudheer Kumar, Madhumita Srivastava, and Alok Kumar Srivastava 2 The Plant Microbiome in Agricultural Sustainability: From Microbe to Microbiome 31Jose Pedro Fonseca, Yuan Wang, and Kirankumar S. Mysore 3 Seed Microbiome and Its Implication in Plant Growth Promotion and Health 47Padmavathi Tallapragada and Usha Seshachla 4 Microbiome: The Holobiont, Its Application and Effect on the Plant System 65Pragati Sahai and Vimlendu Bhushan Sinha 5 Ecology of the Diazotrophic Microbiome 81Preeti Singh, Rahul Kunwar Singh, Dhananjay Kumar, and Shree Prakash Tiwari 6 Functional Microbiome for Crop Improvement Under a Changing Environment 101Abbaci Hocine, Bensidhoum Leila, Houali Karim, and Nabti Elhafid 7 Functional Importance of the Phyllosphere Microbiome and Its Implications in Agriculture 119Parasuraman Paramanantham, Subhaswaraj Pattnaik, and Siddhardha Busi 8 Microbial Consortia: Emerging Conglomerate for Better and Superior Sustainable Agricultural Practices 141Rishi Kumar Verma, Manisha Sachan, and Shivesh Sharma 9 Rhizomicrobiome for Sustainable Crop Growth and Health Management 157Tualar Simarmata, Mieke R. Setiawati, Betty N. Fitriatin, and Diyan Herdiyantoro 10 Mycorrhizal Microbiome: An Ideal Association in Sustainable Agriculture 195Baby Summuna, Sachin Gupta, and Moni Gupta 11 Microbiome-Driven Nutrient Fortification in Plants: The Role of Microbiota in Chemical Transformation and Nutrient Mobilization 211Irina Sidorova and Elena Voronina 12 Engineering Microbes to Improve Crop Health: A New Dimension for Sustainable Agricultural Productivity 231P. Veera Bramhachari, A.M.V.N. Prathyusha, and Ganugula Mohana Sheela 13 Biotechnology of Plant-Associated Microbiomes 243Son Truong Dinh, Van T. Luu, Long Hoa Hoang, Xuan Canh Nguyen, and Cuong Tu Ho 14 Microbiome Genomics and Functional Traits for Agricultural Sustainability 279Amy Novinscak, Antoine Zboralski, Roxane Roquigny, and Martin Filion Index 299

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Book SynopsisA Detailed Reference on How Modern Biotechnology is using the Biofortification of Crops to Improve the Vitamin and Mineral Content of Edible Plants In this reference, Vitamins and Minerals Bio-Fortification of Edible Plants, authors cover new territory on phytonutrients, focusing on the enhancement and modification of edible crops. This book presents techniques and research findings from modern biotechnology to educate readers on the newest tools and research in the field. Readers will learn how groundbreaking scientific advances have contributed to the nutritional content of edible plants and crops for animals and humans. Inside, readers will find comprehensive information on new concepts of biofortification, including but not limited to: ? Modern biotechnology and its uses for improving the vitamin and mineral content of edible plants ? Potential minerals and vitamins that can be targeted and implemented in agriculture ? Ways of enhancing the nutritional contents of edible plants to address nutritional deficiencies and improve livestock ? Methods of identifying plants that can be used to heal or prevent disease and illness While many books cover the phytonutrients of crops, this reference book reports on methodologies, techniques, and environmental changes used to enhance and improve agricultural products. It is one of the first to provide information on using modern biotechnologies to modify crops with the goal of creating health benefits.Table of ContentsList of Contributors vii Foreword xi 1 Biofortification of Edible Plants: Set the Stage for Better Nutrition 1Noureddine Benkeblia 2 Food Fortification: What’s in It for the Malnourished World? 27Barbara Poniedziałek, Kinga Perkowska, and Piotr Rzymski 3 Modern Biotechnologies and Mineral Biofortification of Edible Crops 45Noureddine Benkeblia and Kathleen L. Hefferon 4 Biotechnologies and Vitamins Biofortification of Edible Crops 71Noureddine Benkeblia and Kathleen L. Hefferon 5 Carotenoids Biofortification of Sweet Potatoes 87Noureddine Benkeblia, Elisabete M. Pinto, and Marta W. Vasconcelos 6 Improving Iron Nutrition in Plant Foods: The Role of Legumes and Soil Microbes 103Mariana Roriz, Marta Barros, Paula M. L. Castro, Susana M. P. Carvalho, and Marta W. Vasconcelos 7 Biofortification of Carotenoids in Agricultural and Horticultural Crops: A Promising Strategy to Target Vitamin A Malnutrition 123Hulikere Jagdish Shwetha, Shivaprasad Shilpa, Bangalore Prabhashankar Arathi, Marisiddaiah Raju, and Rangaswamy Lakshminarayana 8 Agronomic Biofortification from a Stakeholder’s Viewpoint: Evidence from Studies on Iodine-Enriched Foods in Uganda 163Solomon Olum, Joshua Wesana, Walter Odongo, Joseph Mogendi, Collins Okello, Dominic Webale, Anselimo Makokha, Duncan Ongeng, Xavier Gellynck, and Hans De Steur 9 Biofortification of Cereals through Foliar Application of Minerals 191Shahid Hussain, Ayta Umar, Mamoona Amir, and Muhammad Aon10 NAS Overexpression and Rice Zinc Biofortification: An Insight, Current Knowledge, and Outlook 223Yuta Kawakami and Navreet K. Bhullar Index 235

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Book SynopsisPresents the latest knowledge of improving the stress tolerance, yield, and quality of rice crops One of the most important cereal crops, rice provides food to more than half of the world population. Various abiotic stressescurrently impacting an estimated 60% of crop yieldsare projected to increase in severity and frequency due to climate change. In light of the threat of global food grain insecurity, interest in molecular rice breeding has intensified in recent years. Progress has been made, but there remains an urgent need to develop stress-tolerant, bio-fortified rice varieties that provide consistent and high-quality yields under both stress and non-stress conditions. Molecular Breeding for Rice Abiotic Stress Tolerance and Nutritional Quality is the first book to provide comprehensive and up-to-date coverage of this critical topic, containing the physiological, biochemical, and molecular information required to develop effective engineering strategies for enhancing rice yield.Table of ContentsPreface xix List of Contributors xxi 1 Rice Adaptation to Climate Change: Opportunities and Priorities in Molecular Breeding 1Vikram Jeet Singh, Kunnummal Kurungara Vinod, Subbaiyan Gopala Krishnan and Ashok K. Singh 2 Molecular Breeding for Improving Salinity Tolerance in Rice: Recent Progress and Future Prospects 26Sandeep Chapagain, Lovepreet Singh, Richard Garcia, Rajat Pruthi, Jonathan Concepcion, Sapphire Coronejo and Prasanta K. Subudhi 3 Molecular Breeding for Improving Drought Tolerance in Rice: Recent Progress and Future Perspectives 53Ratna R. Majumder, Sandeep Sakhale, Shailesh Yadav, Nitika Sandhu, Lutful Hassan, Md. Amir Hossain and Arvind Kumar 4 Molecular Breeding for Improving Flooding Tolerance in Rice: Recent Progress and Future Perspectives 75Ramani K. Sarkar, Jangi N. Reddy and Satya R. Das 5 Molecular Breeding for Improving Heat Stress Tolerance in Rice: Recent Progress and Future Perspectives 92Bui Chi Buu, Cho Young Chan and Nguyen Thi Lang 6 Molecular Breeding for Improving Cold Tolerance in Rice: Recent Progress and Future Perspectives 120Ning Xiao and Jian-Min Chen 7 Molecular Breeding for Lower Cadmium Accumulation in Rice Grain: Progress and Perspectives 131Dongping Li, Xiaohua Hao and Liangbi Chen 8 Molecular Breeding for Improving Arsenic Stress Tolerance in Rice: Recent Progress and Future Perspectives 163Nourollah Ahmadi and Julien Frouin 9 Molecular Breeding for Improving Ozone Tolerance in Rice: Recent Progress and Future Perspectives 180Md. Ashrafuzzaman, Robert Henry and Michael Frei 10 Molecular Breeding Strategies for Enhancing Rice Yields Under Low Light Intensity 201Mayank Rai, Suvendhu S. Dutta and Wricha Tyagi 11 Harnessing Tolerance to Low Phosphorus in Rice: Recent Progress and Future Perspectives 215Wricha Tyagi, Erneica N. Nongbri and Mayank Rai 12 Molecular Breeding for Improving Nitrogen Use Efficiency in Rice: Progress and Perspectives 234Chirravuri N. Neeraja, Sitapati R. Voleti, Subrahmanyam Desiraju, Surekha Kuchi, Sonali Bej, Krishnakanth Talapanti and Raghuveer R. Puskur 13 Dissecting the Molecular Basis of Drought-Induced Oxidative Stress Tolerance in Rice 249Amit K. Pradhan, Sabnoor Y. Jyoti, Zina M. Shandilya, Mehzabin Rehman, Debanjali Saikia, Junu Poudel, Jyotirmay Kalita, Kongkona Borborah, Uma K. Chowra, Jnandabhiram Chutia, Lakshminarayana R. Vemireddy and Bhaben Tanti 14 Manipulation of Photosynthesis to Increase Rice Yield Potential 274Prabuddha Dehigaspitiya and Saman Seneweera 15 Molecular Breeding for Improved β-carotene Synthesis in Golden Rice: Recent Progress and Future Perspectives 287Swapan K. Datta, Shuvobrata Majumder and Karabi Datta 16 Increasing Grain Zinc Concentration in Rice 304Naoya Miyazaki, Miki Ogasawara and Ryo Ishikawa 17 Molecular Breeding for Iron Bio-Fortification in Rice Grain: Recent Progress and Future Perspectives 315Elssa Pandit, Swapnil Pawar, Priyadarshini Sanghamitra and Sharat K. Pradhan 18 Aromatic Rices: Evolution, Genetics and Improvement through Conventional Breeding and Biotechnological Methods 341Lakshminarayana R. Vemireddy, Bhaben Tanti, Lipika Lahkar and Zina M. Shandilya 19 Genetic Engineering for Increasing Antioxidant Content in Rice: Recent Progress and Future Perspectives 358Qinlong Zhu, Jiantao Tan, Bin Wang and Yao-Guang Liu 20 Molecular Breeding Approaches for Improvement and Development of Water Saving Aerobic Rice 382Rahul K. Meena, Kuldeep Kumar, Saurabh K. Dubey, Ashish K. Singh, Adarsh Kumar, Deepanshu Jayaswal, Badal Singh, Rajinder Jain and Sunita Jain 21 Targeting the Ascorbate-Glutathione Pathway and the Glyoxalase Pathway for Genetic Engineering of Abiotic Stress-Tolerance in Rice 398Mohammad A. Hossain, Tahsina S. Hoque, Abbu Zaid, Shabir H. Wani, Mohammad G. Mostofa and Robert Henry Index 428

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Book SynopsisWheat is produced on a greater area, grown over a wider geographic range, and traded internationally as a commodity more than any other arable crop. Wheat alone provides 20% of the calories and protein in the global human diet. Understanding the interactions between wheat production, the environment, and human nutrition is essential for meeting the demands of food security as we approach the middle of the 21st century. Wheat: Environment, Food and Health is written by two leading authorities in the field and offers insights into critical issues such as the sustainability of wheat production, the challenges of both mitigating and adapting to environmental change, and the effects of wheat consumption on human health. Covering a broad range of topics, the authors: Introduce the historical development and utilization of the wheat crop. Describe the factors affecting the quality and acceptability of wheat for different uses. Table of ContentsForeword xv Acknowledgements xvi 1 Wheat and Humans: An Introduction to the Development and Utilisation of the Wheat Crop 1 1.1 Wheat Production in the Past and Present 1 1.1.1 Co-Evolution of Wheat Production and Human Societies 1 1.1.2 Wheat Supply and Demand 4 1.1.3 Wheat Adaptation 7 1.2 The Wheat Plant 9 1.2.1 Vegetative Phase 14 1.2.1.1 Germination 14 1.2.1.2 Leaves 15 1.2.1.3 Tillers 16 1.2.1.4 Roots 16 1.2.2 Reproductive Phase 16 1.2.2.1 Stem Extension 17 1.2.2.2 Booting and Ear Emergence 18 1.2.2.3 Anthesis 18 1.2.2.4 Grain Growth 19 1.3 Wheat Evolution and Migration 20 1.3.1 Origin in the Fertile Crescent 20 1.3.2 Wild Wheats 21 1.3.3 Domestication 22 1.3.4 The Spread of Wheat Cultivation 23 1.3.5 Increases in Harvest Index 24 1.4 Wheat as Food 25 1.4.1 The Development of Milling and Baking 25 1.4.2 The Cultural Significance of Bread 28 1.4.3 Bread Today 30 1.4.4 The Fall and Rise of Whole Grain Foods 31 1.4.5 Producing White and Wholemeal Flours by Roller Milling 33 1.5 Grain Quality 33 1.5.1 Grain Size, Shape, and Specific Weight 33 1.5.2 Endosperm Texture 35 1.5.3 Water Absorption 35 1.5.4 Gluten 36 1.5.4.1 The Origin and Properties of Gluten 36 1.5.4.2 Gluten and Health 37 1.5.4.3 Dough Properties that Determine Processing Quality 37 1.5.4.4 Importance of Total Protein Concentration 38 1.5.4.5 Importance of Protein Quality 40 1.5.4.6 Measurement of Dough Rheology and Quality 40 1.5.5 Other Factors Affecting the Acceptability of Wheat for Different End-Uses 41 1.5.5.1 Alpha-Amylase Activity 41 1.5.5.2 Seed Coat Colour 42 1.6 Further Chapters 42 References 42 2 A ‘Good’ Soil 52 2.1 Soils for Wheat Production 53 2.1.1 Soil Taxonomy 53 2.1.2 Soil Texture 54 2.1.3 Soil Organic Matter 56 2.1.4 Soil pH and Sodicity 58 2.1.5 Salinity 60 2.1.6 Soil Structure 61 2.1.7 Soil Depth 63 2.1.8 Land Classification 63 2.2 The Rise of the Plough 64 2.3 Soil Change and Land Degradation 66 2.3.1 Loss of Soil 66 2.3.2 Organic Matter Loss and Amendment 70 2.3.3 Acidification and Liming 74 2.3.3.1 Calcium as a Nutrient 75 2.3.4 Depletion of Micronutrients 76 2.3.4.1 Boron 76 2.3.4.2 Chlorine 76 2.3.4.3 Copper 77 2.3.4.4 Iron 77 2.3.4.5 Manganese 78 2.3.4.6 Molybdenum 78 2.3.4.7 Nickel 78 2.3.4.8 Zinc 79 2.3.5 Salinisation 79 2.3.6 The Weed Seedbank 80 2.4 Systems for Protecting the Soil 82 2.4.1 Conservation Tillage 82 2.4.2 Organic Farming 84 2.4.3 Conservation Agriculture 85 2.5 Land-Use Efficiency and Soils 86 References 87 3 Ample Water 101 3.1 The Water Requirement of Wheat 103 3.1.1 Germination and Seedling Emergence 103 3.1.2 Transpiration 104 3.1.3 Root Growth 108 3.1.4 Reproductive Growth and Grain Filling 109 3.2 Available Water 113 3.2.1 Soil Water 113 3.2.2 Rainfall 114 3.2.2.1 Rainfall Shortage 115 3.2.2.2 Rainfall Excess 116 3.2.3 Irrigation 117 3.2.3.1 Surface Irrigation 119 3.2.3.2 Overhead Irrigation 119 3.2.3.3 Sources of Irrigation Water 120 3.3 Water Use Efficiency 122 3.3.1 Reducing Evaporation Losses 122 3.3.2 Increasing Rooting at Depth 122 3.3.3 Deficit Irrigation 124 3.3.4 Osmotic Adjustment 124 3.3.5 Transpiration Efficiency 125 3.3.6 Potassium 125 3.4 Land-Use Efficiency and Water 127 References 128 4 Mild Temperatures 139 4.1 The Temperature Requirement for Wheat 140 4.2 ‘Waiting for Fine Times’ (Snape et al. 2001) 142 4.2.1 Dormancy 142 4.2.2 Cold Acclimation 143 4.2.3 Vernalisation 144 4.2.4 Photoperiodism 145 4.2.5 Earliness per se 147 4.3 Vegetative Growth and Development 147 4.3.1 Germination and Emergence 147 4.3.2 Leaves 148 4.3.3 Tillers 150 4.3.4 Roots 150 4.4 Reproductive Growth and Development 151 4.4.1 Spikelet Formation and Stem Extension 151 4.4.2 Meiosis and Anthesis 151 4.4.2.1 Heat Stress 151 4.4.2.2 Cold Stress 154 4.4.3 Grain Filling and Quality 154 4.5 Global Warming 156 References 157 5 Sunshine 166 5.1 The Light Requirement of Wheat 170 5.1.1 Light Quantity 170 5.1.2 Light Quality 175 5.2 Light Interception 176 5.3 Improving Radiation Use for Increased Land-Use Efficiency 179 References 181 6 Canopy Management 186 6.1 Crop Establishment 186 6.1.1 Sowing Date 186 6.1.2 Plant Populations and Sowing Rate 188 6.2 Crop Nutrition 193 6.2.1 Nitrogen 194 6.2.1.1 The Requirement for Nitrogen 194 6.2.1.2 Nitrogen Fixation 201 6.2.1.3 Nitrogen Efficiencies and Losses 205 6.2.1.4 Recovering and Recycling Fixed Nitrogen 211 6.2.1.5 Optimising Nitrogen Application 214 6.2.2 Phosphorus 218 6.2.3 Sulphur 221 6.2.4 Magnesium 224 6.3 Diseases and their Control 224 6.3.1 The Rusts 226 6.3.1.1 Yellow Rust 226 6.3.1.2 Leaf Rust 227 6.3.1.3 Stem Rust 227 6.3.2 The Blotch Diseases 228 6.3.2.1 Septoria tritici Blotch 228 6.3.2.2 Septoria nodorum Blotch 229 6.3.2.3 Tan Spot 230 6.3.3 Diseases Contributing to Mycotoxins in the Grain 230 6.3.3.1 Ergot 230 6.3.3.2 Fusarium Head Blight (FHB) 231 6.3.4 Fungicides and Fungicide Use 232 6.4 Land-use Efficiency and Canopy Management 238 References 240 7 The Structure and Composition of the Wheat Grain 263 7.1 Grain Development 263 7.1.1 Fertilisation 263 7.1.2 Post-fertilisation 265 7.1.3 Endosperm Development 265 7.1.4 Embryo Development 267 7.2 Structure of the Mature Grain 268 7.3 Major Components of the Mature Grain 271 7.3.1 Carbohydrates 272 7.3.1.1 Monosaccharides, Disaccharides, and Oligosaccharides 272 7.3.1.2 Starch 272 7.3.1.3 Cell Wall Polysaccharides 274 7.3.1.4 Arabinogalactan Peptide (AGP) 276 7.3.2 Proteins 277 7.3.2.1 Grain Protein Content (GPC) 277 7.3.2.2 Grain Protein Deviation 277 7.3.2.3 Essential Amino Acid Composition 278 7.3.2.4 Wheat Grain Proteins 279 7.3.2.5 Gluten Proteins: Gliadins and Glutenins 280 7.3.2.6 Other Proteins of the Prolamin Superfamily 287 7.3.2.7 Other Storage Proteins 291 7.3.2.8 Other Inhibitors and Putative Defensive Proteins 292 7.3.2.9 Xylanases and Xylanase Inhibitors 293 7.3.3 Lipids 293 7.3.4 Minor Components: Minerals, Vitamins, and Phytochemicals 294 7.4 Gradients in Composition within the Starchy Endosperm 295 References 296 8 Components and Mechanisms that Determine Grain Processing Properties 301 8.1 Grain Hardness and Vitreousness 301 8.1.1 Friabilin and Puroindolines 302 8.1.2 Other Proteins that Affect Grain Hardness 303 8.1.3 Role of Lipids 304 8.1.4 When and How is Grain Softness Established? 304 8.1.5 Vitreousness 305 8.2 Dough Viscoelasticity 305 8.2.1 Wheat Gluten and Dough Viscoelasticity 305 8.2.2 HMW Subunits, Dough Strength, and Breadmaking Quality 307 8.2.3 Effects of Other Gluten Proteins on Dough Quality 308 8.2.4 Molecular Basis for the Role of the HMW Subunits in Gluten Structure and Properties 308 8.3 Functional Properties of Starch 309 8.3.1 Starch Gelatinisation 310 8.3.2 Starch Damage 310 8.3.3 Starch Retrogradation and Staling 311 8.3.4 Waxy and High Amylose Starches 311 8.4 Other Functional Components 311 8.4.1 Arabinoxylan 311 8.4.2 Functional Properties of Lipids in Dough 312 8.4.3 Water Absorption: Effects of Starch, Protein, and Fibre 312 8.5 Effects of Crop Nutrition and Environmental Factors on Grain Composition and Quality 313 8.5.1 Nitrogen Fertilisation 313 8.5.2 Sulphur Availability 314 8.5.2.1 Sulphur Nutrition, Asparagine Content, and Acrylamide Formation 315 8.5.3 Temperature and Water Availability 316 8.5.4 Carbon Dioxide Concentration 317 References 318 9 The Role of Wheat in Diet and Health 321 9.1 Contribution of Wheat to the Human Diet 321 9.2 Dietary Fibre 321 9.2.1 Proposed and Approved Benefits of Dietary Fibre 321 9.2.2 Wheat Grain Fibre 324 9.2.2.1 Cell Wall Polysaccharides 324 9.2.2.2 Fructans 325 9.2.2.3 Resistant Starch 325 9.2.2.4 High Amylose Starch 325 9.2.3 Mechanism of Action of Dietary Fibre 326 9.2.3.1 Role of Food Structure and Breakdown 326 9.2.3.2 Role of Luminal Viscosity 327 9.2.3.3 Role of Prebiotic Activity 327 9.3 Micronutrients and Phytochemicals 327 9.3.1 Iron and Zinc 327 9.3.2 Selenium 330 9.3.3 B Vitamins 330 9.3.4 Phytochemicals 331 9.3.4.1 Phenolics 331 9.3.4.2 Terpenoids 333 9.3.5 Betaine and Choline 333 9.3.6 Health Benefits of Phytochemicals 335 9.3.7 Environmental Effects on the Concentrations of Phytochemicals and Minerals 337 9.4 Adverse Effects of Wheat on Health 338 9.4.1 Wheat as Part of the Western Diet 338 9.4.2 Allergy and Intolerance to Wheat 338 9.4.3 Allergy 338 9.4.4 Coeliac Disease and Related Intolerances 340 9.4.5 Other Adverse Reactions to Wheat 341 9.4.6 FODMAPs and Gastro-Intestinal Disorders 341 9.4.7 Bloating 342 9.5 Producing Healthier Wheat Products by Processing 342 9.5.1 Debranning 342 9.5.2 Flour Particle Size 342 9.5.3 Fermentation 343 9.5.4 Sprouting 344 9.5.5 Enzyme Treatments 344 9.5.6 Conclusions: Processing for Improved Health Benefits 344 9.6 Fungal Toxins in Wheat 345 9.6.1 Ergot 345 9.6.2 Fusarium Mycotoxins 345 9.6.3 Mycotoxins from Storage Fungi 347 9.6.4 Removing Fungal Toxins by Processing 347 References 348 10 Wheat Genetics and Improvement 357 10.1 Genetic Background to Wheat Breeding 357 10.2 Technologies for Wheat Genetics and Breeding 358 10.2.1 Aneuploid Lines 358 10.2.2 Doubled Haploid Lines, Recombinant Inbred Lines, and Near-Isogenic Lines 359 10.2.3 Marker-Assisted Selection (MAS) 360 10.2.4 Genome-Wide Association Genetics (GWAS) and Genomic Selection (GS) 360 10.2.5 Intermated Populations (MAGIC and NAM) 361 10.2.6 Hybrid Wheat 361 10.2.7 Perennial Wheat 362 10.3 Sources and Exploitation of Genetic Diversity 363 10.3.1 Gene Banks 363 10.3.2 Land Races 363 10.3.3 Wild Relatives 364 10.3.4 Rye Translocations 365 10.3.5 Synthetic Wheats 366 10.3.6 Ancient Wheats 366 10.3.7 Tritordeum: A Novel Cereal Derived from Wheat 367 10.3.8 Mutagenesis and TILLING 367 10.4 Impact of Breeding on Genetic Diversity in Wheat 369 10.4.1 Minerals 369 10.4.2 Protein Content 370 10.4.3 Wheat Proteins that Trigger Adverse Reactions 371 10.4.4 Dietary Fibre 371 10.4.5 Other Components 372 10.5 Are Ancient Wheats More Healthy than Modern Wheats? 372 10.5.1 Wheat Proteins that Trigger Adverse Reactions 373 10.5.2 Other Components 373 10.6 Wheat Biotechnology 374 10.6.1 Genetic Transformation 374 10.6.1.1 DNA Delivery 375 10.6.1.2 Selection of Transformed Plants 375 10.6.1.3 Targeting and Regulating Gene Expression 376 10.6.1.4 Gene Editing 376 10.6.2 Regulation, Impact and Consumer Acceptance of Genetic Transformation and Genome Editing in Wheat and Other Crops 377 10.7 Applications of Biotechnology to Wheat Improvement 378 10.7.1 Input Traits 379 10.7.1.1 Potential Yield 379 10.7.1.2 Improving Nitrogen-Use Efficiency (NUE) 379 10.7.1.3 Resistance to Abiotic Stresses 380 10.7.1.4 Resistance to Pests and Pathogens 380 10.7.2 Output Traits: Grain Quality 380 10.7.2.1 Dough Strength 380 10.7.2.2 Grain Texture 382 10.7.2.3 Increasing Mineral Micronutrients 382 10.7.2.4 Reducing Adverse Effects 383 10.7.2.5 ‘Improving’ Grain Polysaccharides 384 References 385 11 Epilogue: Wheat in Conflict and in Peace 394 Reference 396 Index 397

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Book SynopsisTable of ContentsList of Contributors x Preface xvii About the Editor xix Acknowledgments xxi 1 An Overview of Genome-Engineering Methods 1Sushmita, Gurminder Kaur, Santosh Kumar Upadhyay, and Praveen Chandra Verma 2 Distribution of Nutritional and Mineral Components in Important Crop Plants 22Katarina Vogel-Mikuš, Paula Pongrac, Ivan Kreft, Primož Pelicon, Primož Vavpetič, Boštjan Jenčič, Johannes Teun van Elteren, Peter Kump, Sudhir P. Singh, and Marjana Regvar 3 Application of Genome Engineering Methods for Quality Improvement in Important Crops 43Sajid Fiaz, Sher Aslam Khan, Galal Bakr Anis, Habib Ali, Mohsin Ali, Kazim Ali, Mehmood Ali Noor, Sibtain Ahmad, and Bilal Ahmad Asad 4 Genome Engineering for Enriching Fe and Zn in Rice Grain and Increasing Micronutrient Bioavailability 69Conrado Dueñas, Jr., Gela Myan B. Mota, Norman Oliva, and Inez H. Slamet-Loedin 5 Development of Carotenoids Rich Grains by Genome Engineering 83Vikrant Gautam, Gurwinder Singh Rana, Pankaj Kumar, and Santosh Watpade 6 CRISPR-Cas9 System for Agriculture Crop Improvement 97Ashish Sharma, Poorwa Kamal Badola, and Prabodh Kumar Trivedi 7 Contribution of Crop Biofortification in Mitigating Vitamin Deficiency Globally 112Siddhant Chaturvedi, Roni Chaudhary, and Siddharth Tiwari 8 Genome Editing Approaches for Trait Improvement in the Hairy Root Cultures of the Economically Important Plants 131Pravin Prakash, Rakesh Srivastava, Ajay Kumar, Gurminder Kaur, and Praveen Chandra Verma 9 Phytic Acid Reduction in Cereal Grains by Genome Engineering: Potential Targets to Achieve Low Phytate Wheat 146Ajay K. Pandey, Sipla Aggarwal, Varsha Meena, and Anil Kumar 10 Genome Engineering for Nutritional Improvement in Pulses 157Chirag Uppal, Ajinder Kaur, and Chhaya Sharma 11 The Survey of Genetic Engineering Approaches for Oil/Fatty Acid Content Improvement in Oilseed Crops 181Kaushal Kumar Bhati, Riyazuddin Riyazuddin, Ashish Kumar Pathak, and Anuradha Singh 12 Genome-Editing Mediated Improvement of Biotic Tolerance in Crop Plants 199Krishan Mohan Rai and Harpal Singh 13 Genome Engineering and Essential Mineral Enrichment of Crops 210Erum Shoeb, Uzma Badar, Srividhya Venkataraman, Ghyda Murad Hashim, and Kathleen Hefferon 14 Genome Editing to Develop Disease Resistance in Crops 224Kashaf Zafar, Azka Noureen, Muhammad Jawad Akbar Awan, Naveed Anjum, Muhammad Qasim Aslam, Muhammad Zuhaib Khan, Imran Amin, and Shahid Mansoor 15 Biotechnological Approaches for Nutritional Improvement in Potato (Solanum tuberosum L.) 253Chandrama Prakash Upadhyaya and Deepak Singh Bagri 16 Genome Engineering Strategies for Quality Improvement in Tomato 281Tian Wang, Hongyan Zhang, and Hongliang Zhu 17 Genome Editing for Biofortification of Rice: Current Implications and Future Aspects 297Suchismita Roy and Praveen Soni 18 Genome Editing for Improving Abiotic Stress Tolerance in Rice 314Shweta Roy, Nirbhay Kumar Kushwaha, Hasthi Ram, and Praveen Soni 19 Role of Genome Engineering for the Development of Resistant Starch-Rich, Allergen-Free and Processing Quality Improved Cereal Crops 333Anuradha Singh, Amit Yadav, Joy K. Roy, and Kaushal Kumar Bhati 20 Engineering of Plant Metabolic Pathway for Nutritional Improvement: Recent Advances and Challenges 351Sameer Dixit, Akanchha Shukla, Vinayak Singh, and Santosh Kumar Upadhyay 21 Genome Engineering for Food Security 380Sajid Fiaz, Sher Aslam Khan, Mehmood Ali Noor, Afifa Younas, Habib Ali, Kazim Ali, Mahmoud Mohamed Gaballah, and Galal Bakr Anis Index 391

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Book SynopsisOGENOTYPING BY SEQUENCING FOR CROP IMPROVEMENT A thoroughly up-to-date exploration of genotyping-by-sequencing technologies and related methods in plant science In Genotyping by Sequencing for Crop Improvement, a team of distinguished researchers delivers an in-depth and current exploration of the latest advances in genotyping-by-sequencing (GBS) methods, the statistical approaches used to analyze GBS data, and its applications, including quantitative trait loci (QTL) mapping, genome-wide association studies (GWAS), and genomic selection (GS) in crop improvement. This edited volume includes insightful contributions on a variety of relevant topics, like advanced molecular markers, high-throughput genotyping platforms, whole genome resequencing, QTL mapping with advanced mapping populations, analytical pipelines for GBS analysis, and more. The distinguished contributors explore traditional and advanced markers used in plant genotyping in extensive detail, and advanced genotyping platforTable of ContentsChapter 1: Molecular marker techniques and recent advancementsDharminder Bhatia and Gagandeep Singh Bajwa Chapter 2: High-throughput genotyping platformsSandhya Sharma, Kuldeep Kumar, Kishor Tribhuvan, Reeta, Sandeep Kumar, Priyanka Jain, Swati Saxena, Joshita Vijayan, Harsha Shrivastava and Kishor Gaikwad Chapter 3: Opportunity and challenges for whole genome re-sequencing based genotyping in plantsSurbhi Kumawat, Gaurav Raturi, Pallavi Dhiman, Sreeja Sudhakarn, Nitika Rajora, Vandana Thakaral, Himanshu Yadav, Gunashri Padalkar, Yogesh Sharma, Vinaykumar Rachappanavar and Manish Kumar Chapter 4: QTL mapping using advanced mapping populations and high-throughput genotypingSweta Sinha*, Brij Kishore Kushwaha and Rupesh Deshmukh Chapter 5: Genome-wide association study: approaches, applicability, and challengesAkshay S Sakhare, Suneetha Kota, Santosh Rathod, Brajendra Parmar and Viswanathan C Chapter 6: Genotyping of seeds while preserving their viabilityVinaykumar Rachappanavar, J K Sharma and Himanshu P Chapter 7: Genomic selection: Advances, applicability, and challengesNaina Garewal, Riya Joon, Ravneet Kaur and Kashmir Singh Chapter 8: Analytical pipelines for the GBS analysisVinaykumar Rachappanavar, J K Sharma and Himanshu P Chapter 9: Recent advances and applicability of GBS, GWAS, and GS in maizeAnshuman Tiwari, Shalu Choudhary, Jayendra Padiya, Abhijit Ubale, Venugopal Mikkilineni and Bharat Char Chapter 10: Recent advances and applicability of GBS, GWAS, and GS in soybeanPrashant Raghunath Shingote, Dhananjay Narayanrao Gotarkar, Ravindra Ramrao Kale, Omkar Limbalkar, and Dhiraj Lalji Wasule Chapter 11: Advances and applicability of genotyping technologies in cotton improvementShubham Bhardwaj, Vikas Devkar*, Amit Kumar, Alisha, Shivani Sharma, Rupesh K. Deshmukh and Gunvant B Patil Chapter 12: Recent advances and applicability of GBS, GWAS, and GS in millet cropsPankaj S. Mundada¥, Swapnil B. Kadam¥, Anupama A. Pable and Vitthal T. Barvkar Chapter 13: Recent advances and applicability of GBS, GWAS, and GS in pigeon peaAnuradha Singh and Nisha Singh Chapter 14: Opportunity and challenges for high-throughput genotyping in sugarcanePrathima. P. Thirugnanasambandam, Avinash Singode, Lakshmipathy Talambedu and Senthilkumar Shanmugavel Chapter 15: Recent advances and applicability of GBS, GWAS, and GS in polyploid cropsVandana Thakaral,*, Himanshu Yadav, Gunashri Padalkar, Surbhi Kumawat, Gaurav Raturi, Virender Kumar, Rushil Mandlik, Nitika Rajora and Manipal Singh Chapter 16: Recent advances and applicability of GBS, GWAS, and GS in oilseed cropsSanskriti Vats*, Yogesh Sharma, Virender Kumar, Rushil Mandlik, Surbhi Kumawat, Himanshu Yadav, Pallavi Dhiman, Vandana Thakral, Md Aminul Islam and Sreeja Sudhakaran

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Book SynopsisDiscover the role of nanotechnology in promoting plant growth and protection through the management of microbial pathogens InNanotechnology in Plant Growth Promotion and Protection, distinguished researcher and author Dr.AvinashP. Ingle delivers a rigorous and insightful collection of some of the latest developments in nanotechnologyparticularly relatedto plant growthpromotionand protection. The book focuses broadly on the role played by nanotechnology in growth promotionof plantsandtheirprotectionthroughthe management of different microbial pathogens. You'll learn about a wide variety of topics, including the role of nanomaterials in sustainable agriculture, hownano-fertilizersbehave as soil feed, and the dual role of nanoparticles in plant growthpromotionand phytopathogen management.You'llalso discover why nanotechnology has the potential to revolutionize the current agricultural landscape through the development of nano-based products, like plant growtTable of ContentsList of Contributors xii Preface xvi 1 Nanotechnology as a Smart Way to Promote the Growth of Plants and Control Plant Diseases: Prospects and Impacts 1Heba Mahmoud Mohammad Abdel-Aziz and Mohammed Nagib Abdel-ghany Hasaneen 1.1 Introduction 1 1.2 Nanofertilizers 2 1.2.1 Methods for Application of Nanofertilizers 2 1.2.1.1 Seed Priming 2 1.2.1.2 In Soil 2 1.2.1.3 Foliar Application 3 1.2.2 Possible Ways for Uptake and Translocation of Nanofertilizers in Plants 3 1.2.3 Macronutrient Nanofertilizers 3 1.2.4 Micronutrient Nanofertilizers 5 1.2.5 Non-nutrient Nanofertilizers 6 1.2.6 Advantages of Nanofertilizers 6 1.2.7 Limitations of Nanofertilizers 7 1.3 Nanopesticides and Nanoantimicrobials 7 1.3.1 Nano-Insecticides 8 1.3.2 Nanobactericides 8 1.3.3 Nanofungicides 8 1.3.4 Nano-Antivirals 9 1.3.5 Advantages of Using Nanopesticides 9 1.3.6 Risks of Using Nano-based Agrochemicals 9 1.4 Conclusions 10 References 11 2 Effects of Titanium Dioxide Nanomaterials on Plants Growth 17Martin Šebesta, Illa Ramakanth, Ondřej Zvěřina, Martin Šeda, Pavel Diviš, and Marek Kolenčík 2.1 Introduction 17 2.2 Properties of TiO2NPs Important for Biological Interaction 18 2.3 Pathways and Interaction of TiO2NPs with Plants 20 2.3.1 Foliar Exposure 20 2.3.2 Root Exposure 21 2.3.3 Seed Exposure 22 2.3.4 Interaction of TiO2NPs with Plants 22 2.4 Effect of Different Concentrations of TiO2 NPs on Plants 23 2.5 Benefits of Using TiO2NPs Alone and in Complex Formulations on Plant Growth and Yield 31 2.6 Conclusion and Future Perspective 35 References 37 3 The Emerging Applications of Zinc-Based Nanoparticles in Plant Growth Promotion 45Anil Timilsina and Hao Chen 3.1 Introduction 45 3.2 Applications and Effects of Zn Based NPs on Plant Growth Promotion 46 3.2.1 Zn NPs in Seed Treatments and Its Effects 46 3.2.2 Effects of Zn NPs on Seed Germination 46 3.2.3 Effects of Seed Treatment on Plant Growth 50 3.2.4 Molecular Mechanisms Involved in Effects of Zn NPs on Seed 50 3.3 ZnO NPs in Enhanced Plant Growth 50 3.3.1 Application Methods 51 3.3.2 Effects of Zn NPs on Plant Growth Promotion 51 3.3.2.1 Effects of Zn NPs Via Foliar Application 51 3.3.2.2 Effects of Zn NPs Used in Agar Media and Hydroponic Application 55 3.3.2.3 Effects Zn NPs Through Soil Application 55 3.3.2.4 Effects of Zn NPs on Plant Physiological and Biochemical Changes 56 3.4 Zn NPs in Crop Protection 56 3.4.1 Improvement on Disease Resistance 56 3.4.2 Enhancement of Stress Tolerance 57 3.5 Conclusions 57 References 58 4 Nanofertilizer in Enhancing the Production Potentials of Crops 63C. Sharmila Rahale, K.S. Subramanian, and A. Lakshmanan 4.1 Introduction 63 4.2 Nanofertilizers 64 4.3 Synthesis of Nanofertilizer 64 4.4 Uptake, Translocation, and Fate of Nanofertilizers in Plants 66 4.5 Percolation Studies to Assess Nutrient Release Pattern 67 4.6 Application of Nanofertilizers in Plants 68 4.7 Specific Properties of Nanofertilizers 70 4.8 Biosafety Issues in Nanofertilizer Application 70 4.9 Nanofertilizer Studies at Tamil Nadu Agricultural University (TNAU) 71 4.10 Conclusion 74 References 75 5 Potential Applications of Nanobiotechnology in Plant Nutrition and Protection for Sustainable Agriculture 79Vishnu D. Rajput, Abhishek Singh, Tatiana M. Minkina, Sudhir S. Shende, Pradeep Kumar, Krishan K. Verma, Tatiana Bauer, Olga Gorobtsova, Svetlana Deneva, and Anna Sindireva 5.1 Introduction 79 5.2 Nanomaterial in Sustainable Crop Production 81 5.2.1 Nanomaterial in Soil Management 81 5.2.2 Nanomaterials in Nutrient Use Efficiency (NUE) 82 5.2.3 Nanomaterials in Plant Protection 82 5.2.3.1 Nanomaterials as Nano-Pesticides 83 5.2.3.2 Nanomaterials as Nano-Insecticides 83 5.2.3.3 Nanomaterials as Nano-Fungicides 84 5.2.3.4 Nanomaterials as Nano-Herbicides 84 5.3 Nanomaterials in Crop Improvement 85 5.3.1 Abiotic Stresses 85 5.3.1.1 Drought Stress 86 5.3.1.2 Salinity Stress 86 5.4 Nanomaterials in Plant Genetic Engineering 87 5.4.1 Nanoparticle’s Mediated Transformation 87 5.4.2 Non-vector Mediated Transformation 87 5.5 Future Perspectives and Challenges 88 5.6 Conclusions 89 References 89 6 Immunity in Early Life: Nanotechnology in Seed Science and Soil Feed 93Garima Shandilya and Kirtan Tarwadi 6.1 Introduction 93 6.2 Nano Frontiers in Agricultural Development 94 6.2.1 Nanoagronomics 94 6.2.2 Smart Systems for Agrochemicals Delivery 94 6.2.2.1 Nanocapsules 94 6.2.2.2 Liposomes 96 6.2.2.3 Nanoemulsions 96 6.2.2.4 Nanogels 96 6.2.2.5 Nanoclays 97 6.2.2.6 Nanodispersions 97 6.2.2.7 Nanobionics 97 6.3 Nanotechnology in Agriculture 99 6.3.1 Effects of Nanoparticles on Plants 99 6.3.2 Nanoparticle-Plant Hormones Interactions 99 6.3.3 Effect of Nanoparticles on Crop Quality 100 6.4 Immunity in Early Life 101 6.4.1 Seed 101 6.4.2 Pre-sowing Treatments and Priming as Tools for Better Seed Germination 102 6.4.3 Phenomenon of Seed Priming 102 6.4.4 Gene Therapy for Seed 103 6.4.5 Immuning Seeds Using Nanoparticles 104 6.5 Nanotechnology in Soil Feed and Waste Water Treatment 104 6.6 Conclusions 106 References 107 7 Effects of Natural Organic Matter on Bioavailability of Elements from Inorganic Nanomaterial 113Martin Urík, Marek Kolenčík, Nobuhide Fujitake, Pavel Diviš, Ondřej Zvěřina, Illa Ramakanth, and Martin Šeda 7.1 Introduction 113 7.2 Effect of Natural Organic Matter on Nanoparticles’ Aggregation and Agglomeration 114 7.3 Natural Organic Matter Effects on Nanoparticles’ Dissolution 116 7.4 Effect of Mutual Interactions of Natural Organic Matter and Nanoparticles on Their Bioavailability 117 7.5 Conclusions 120 References 120 8 Induction of Stress Tolerance in Crops by Applying Nanomaterials 129Yolanda González-García, Magín González-Moscoso, Hipólito Hernández-Hernández, Alonso Méndez-López, and Antonio Juárez-Maldonado 8.1 Introduction 129 8.2 Impact of Stress on Crops 130 8.2.1 Losses of Crops Due to the Main Stress Conditions 130 8.2.2 Plant Responses to Abiotic Stress 133 8.2.3 Plant Responses to Biotic Stress 135 8.3 Impact of Nanomaterials on Crops 137 8.3.1 Induction of Tolerance to Abiotic Stress by the Application of Nanomaterials 138 8.3.2 Induction of Tolerance to Biotic Stress by the Application of Nanomaterials 146 8.4 Conclusions 151 References 151 9 Nanoparticles as Elicitors of Biologically Active Ingredients in Plants 170Sumaira Anjum, Amna Komal, Bilal Haider Abbasi, and Christophe Hano 9.1 Introduction 170 9.2 Routes of Exposure, Uptake, and Interaction of NPs into Plant Cells 172 9.3 Elicitation of BAIs of Plants by Nanoelicitors 175 9.3.1 Elicitation of Polyphenols by Nanoelicitors 175 9.3.2 Elicitation of Alkaloids by Nanoelicitors 184 9.3.3 Elicitation of Terpenoids by Nanoelicitors 186 9.3.4 Elicitation of Essential Oils by Nanoelicitors 189 9.4 Mechanism of Action of Nanoelicitors 191 9.5 Conclusions 191 References 193 10 Dual Role of Nanoparticles in Plant Growth and Phytopathogen Management 203Tahsin Shoala 10.1 Introduction 203 10.2 Nanoparticles: Notion and Properties 206 10.3 Mode of Entry, Uptake, Translocation and Accumulation of Nanoparticles in Plant Tissues 207 10.4 Nanoparticle–Plant Interactions 208 10.5 Impact of Nanoparticles 209 10.5.1 Influence of Nanoparticles on Photosynthesis 209 10.5.2 Nanoparticles in Plant Growth 211 10.5.3 Nanoparticles in Enhancement of Root and Shoot Growth 212 10.5.4 Impact of Nanoparticles in Phytopathogen Suppression 213 10.6 Conclusions 214 References 215 11 Role of Metal-Based Nanoparticles in Plant Protection 220Avinash P. Ingle and Indarchand Gupta 11.1 Introduction 220 11.2 Nanotechnology in Agriculture 221 11.3 Metal-Based Nanoparticles in Plant Protection 222 11.3.1 Silver-Based Nanoparticles 222 11.3.2 Copper-Based Nanoparticles 224 11.3.3 Zinc-Based Nanoparticles 225 11.3.4 Magnesium Oxide Nanoparticles 226 11.3.5 Titanium Dioxide Nanoparticles 227 11.3.6 Other Metal-Based Nanoparticles 228 11.4 Possible Antimicrobial Mechanisms for Metal-Based Nanoparticles 228 11.4.1 Cell Membrane Damage 229 11.4.2 ROS Generation 230 11.4.3 DNA Damage 230 11.5 Conclusions 230 References 231 12 Role of Zinc-Based Nanoparticles in the Management of Plant Diseases 239Anita Tanwar 12.1 Introduction 239 12.2 Plant Diseases and Their Symptoms 241 12.3 Importance of Zn for Plants 242 12.4 Distribution of Zn in Plants 242 12.5 Efficiency of Zn in Plants 243 12.6 Deficiency Symptoms 243 12.7 Effects of Zn on Microbial Activity 245 12.8 Nanotechnology and Agriculture 246 12.9 Zn-Based Nanoparticles in Plants 247 12.9.1 ZnONPs 249 12.9.1.1 Antimicrobial Activity 250 12.9.1.2 Seed Germination and Plant Growth 251 12.9.1.3 Mechanism of Action of ZnONPs 252 12.10 Conclusions 253 References 253 13 Effects of Different Metal Oxide Nanoparticles on Plant Growth 259Harris Panakkal, Indarchand Gupta, Rahul Bhagat, and Avinash P. Ingle 13.1 Introduction 259 13.2 Effects of Nanoparticles on Plant Growth and Development 261 13.2.1 Effect of Titanium Dioxide Nanoparticles on Plant Growth 262 13.2.2 Effect of Copper Oxide Nanoparticles on Plant Growth 263 13.2.3 Effect of Iron Oxide Nanoparticles on Plant Growth 264 13.2.4 Effect of Zinc Oxide Nanoparticles on Plant Growth 264 13.2.5 Effect of Cerium Oxide Nanoparticles on Plant Growth 266 13.2.6 Effect of Other Nanoparticles on Plant Growth 268 13.3 Mechanisms of Nanoparticles and Plant Interactions 269 13.4 Conclusions 271 References 271 14 Biostimulation and Toxicity: Two Levels of Action of Nanomaterials in Plants 283Adalberto Benavides-Mendoza, Magín González-Moscoso, Dámaris Leopoldina Ojeda-Barrios, and Laura Olivia Fuentes-Lara 14.1 Introduction 283 14.2 Induction of Biostimulation or Toxicity in Plants Due to the Physical Properties of the NMs 285 14.3 Induction of Biostimulation or Toxicity in Plants Due to the Chemical Properties of NM Core and the Composition of Corona 290 14.4 Examples of Biphasic Phenotypic Responses of Plants to Nanomaterials Concentration 294 14.5 Conclusions 298 References 299 15 Toxicological Concerns of Nanomaterials in Agriculture 304Ryan Rienzie and Nadeesh Adassooriya 15.1 Introduction 304 15.2 Uptake and Translocation of Nanomaterials 305 15.3 Mechanisms and Factors Affecting Uptake and Translocation of Nanomaterials 305 15.4 Nature and Factors Affecting Nanomaterial Phytotoxicity 306 15.5 Non-Metallic Nanomaterials 307 15.5.1 Carbon Nanotubes (CNTs) 307 15.5.1.1 Graphene Family Nanomaterials 308 15.5.1.2 Mesoporous Carbon Nanoparticles 308 15.5.1.3 Carbon Dots 308 15.5.2 Nanoclay-Based Systems 309 15.5.3 Nano-Hydroxyapatite (nHAP) 309 15.5.4 Nanoplastics 309 15.6 Metallic Nanoparticles 310 15.6.1 Silver Nanoparticles (AgNPs) 310 15.6.2 Mn-Based Nanoparticles 310 15.6.3 NiO Nanoparticles 311 15.6.4 ZnO Nanoparticles 311 15.6.5 TiO2 Nanoparticles 312 15.6.6 Au Nanoparticles 312 15.6.7 Cu-Based Nanoparticles 313 15.6.7.1 Cu Nanoparticles 313 15.6.7.2 CuO Nanoparticles 313 15.6.8 MgO Nanoparticles 314 15.6.9 CdS Nanoparticles 314 15.6.10 Fe-Based Nanoparticles 314 15.6.11 Al2O3 Nanoparticles 315 15.6.12 Rare Earth Element Nanoparticles 315 15.6.13 Multi-Metallic Nanoparticles 315 15.7 Alteration of Toxic Effects Caused by Nanomaterials; Co-Exposure Experiments 316 15.8 Effects of Nanomaterials on Enzymatic and Non-Enzymatic Defense Systems 318 15.9 Antioxidant-Mediated Removal of Reactive Oxygen Species (ROS) 318 15.10 Effects of Nanomaterials on Micro and Macro Organismal Communities Associated with Soil in Agroecosystems 319 15.10.1 Plant Growth-Promoting Rhizobacteria (PGPR) 319 15.10.2 Effects of Nanomaterials on Soil Dwelling Earthworms 320 15.10.3 Effects on Organisms Associated with Aquatic Ecosystems 321 15.11 Conclusions 321 References 322 Index 331

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Book SynopsisDry Beans and Pulses The second edition of the most complete and authoritative reference on dry beans production, processing, and nutrition available Since the first edition of Dry Beans and Pulses: Production, Processing, and Nutrition was published in 2012, the popularity of pulse crops as sustainable, nutritionally-rich food ingredients for alternate meat and other food products has increased significantly beyond traditional utilization. Retaining its distinctive value-chain approach to the subject, the new edition is fully revised to provide up-to-date coverage of breeding, composition, quality, nutritional profiles, postharvest and processing technologies, food safety and security, significance to human health, and more. A team of more than fifty contributors review recent research, consumer trends, new products, and food security issues in dry beans processing and value-added practices. New chapters address Hard-to-cook phenomenon and Table of ContentsContributors vii Preface xi Part I: Overview, Production and Postharvest Technologies 1 1. Global Production, Trade, Processing and Nutritional Profile of Dry Beans and Other Pulses 3 Muhammad Siddiq, Mark A. Uebersax, and Farihah Siddiq 2. Dry Bean Breeding and Production Technologies 29 Phillip N. Miklas, James D. Kelly, and Karen A. Cichy 3. Physical and Physiological Characteristics and Market Classes of Common Beans 57 Mark A. Uebersax, Carlos Urrea, and Muhammad Siddiq 4. Harvesting, Postharvest Handling, Distribution, and Marketing of Dry Beans 81 Mark A. Uebersax, Muhammad Siddiq, Joe Cramer, and Scott Bales 5. Hard- to- Cook and Other Storage- Induced Quality Defects in Dry Beans 105 Mark A. Uebersax, Muhammad Siddiq, and Makafui Borbi Part II: Composition, Value-added Processing and Quality 129 6. Composition of Raw and Processed Dry Beans and Other Pulses 131 Elham Azarpazhooh and Jasim Ahmed 7. Hydration, Blanching and Thermal Processing of Dry Beans 159 Dharmendra K. Mishra, Norm J. Matella, Rabiha Binti Sulaiman, and Kirk D. Dolan 8. Processing and Quality Evaluation of Canned Dry Beans 191 Brittany L. White, Luke R. Howard, Mark A. Uebersax, and Kirk D. Dolan 9. Extrusion Processing of Dry Beans and Pulses 225 Jose De J. Berrios, Jack N. Losso, and Irene Albertos 10. Processing and Functional Properties of Dry Bean Flours and Fractions 247 Xin Rui and Sharon Hooper 11. Optical Sensing Technologies for Nondestructive Quality Assessment in Dry Beans 277 Fernando A. Mendoza, Jason A. Wiesinger, and Karen A. Cichy 12. Utilization of Dry Beans and Other Pulses as Ingredients in Diverse Food Products 307 Heather Hill 13. Cowpea Composition, Processing, and Products 331 Robert D. Phillips, Firibu Kwesi Saalia, and Nicole Sharon Affrifah 14. Faba (Broad) Bean Production, Processing, and Nutritional Profile 359 Sanju Bala Dhull, Mohd. Kashif Kidwai, Muhammad Siddiq, and Jiwan S. Sidhu 15. Production, Processing, and Nutritional Profile of Chickpeas and Lentils 383 Jiwan S. Sidhu, Tasleem Zafar, Patnarin Benyathiar, and Muhammad Nasir 16. Processing and Utilization of Dry Beans and Pulses in Africa 409 Jose Jackson, Joyce Kinabo, Rosemary Lekalake, and Kebadire Mogotsi 17. Processing and Nutritional Profile of Mung Bean, Black Gram, Pigeon Pea, Lupin, Moth Bean, and Indian Vetch 431 Muhammad Nasir, Jiwan S. Sidhu, and Dalbir Singh Sogi Part III: Culinology, Nutrition, Health Benefits, And Food Security 453 18. A Culinology ® Perspective of Dry Beans and Other Pulses 455 Samir Amin and Carl P. Borchgrevink 19. Nutrition and Human Health Benefits of Dry Beans and Other Pulses 481 Chelsea Didinger, Michelle T. Foster, Marisa Bunning, and Henry J. Thompson 20. Health Implications and Nutrient Bioavailability of Bioactive Compounds in Dry Beans and Other Pulses 505 Jason A. Wiesinger, Frédéric Marsolais, and Raymond P. Glahn 21. A Systems Perspective of the Role of Dry Beans and Pulses in the Future of Global Food Security: Opportunities and Challenges 531 John Medendorp, David DeYoung, Deepa G. Thiagarajan, Randy Duckworth, and Barry Pittendrigh Index 551

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Book SynopsisBioresource Technology Discover the latest developments in the field of bioresource technology with this practical handbook The management and cultivation of bioresources are critical components of the economic survival of nations. Significantly underexplored, recent advances in bioresource technologies have breathed new life into the research and development of new bioresource techniques and capabilities. In Bioresource Technology: Concept, Tools, and Experiences, a team of distinguished researchers delivers a comprehensive work intended to bridge the gap between field-oriented taxonomists and ecologists and lab-oriented functional and molecular biologists. The book is divided into three sections: food, environment, and energy. In the first part, the authors explore the functional food sector, from green and smart food packaging to nanosensors as diagnostic tools in the food industry. The second part is concerned with the achievement of future energy Table of ContentsPart I: The Application of Bioresource Technology in the Functional Food Sector 11 Millets: Robust Entrants to Functional Food Sector 3Sagar Maitra, Sandipan Pine, Pradipta Banerjee, Biswajit Pramanick and Tanmoy Shankar 1.1 Introduction 4 1.2 Nomenclature and Use 5 1.3 Description of Important Millets 7 1.3.1 Sorghum 7 1.3.2 Pearl Millet 7 1.3.3 Finger Millet 8 1.3.4 Foxtail Millet 8 1.3.5 Proso Millet 8 1.3.6 Barnyard Millet 8 1.3.7 Little Millet 9 1.3.8 Kodo Millet 9 1.3.9 Brown-Top Millet 9 1.4 Millets: The Ancient Crops 9 1.5 Current Scenario of Millets Production 10 1.6 Nutritional Importance of Millets 11 1.6.1 Millets as Functional Food 13 1.6.2 Anti-Oxidant and Anti-Aging Properties 14 1.6.3 Protection Against Cancer 15 1.6.4 Anti-Diabetic Properties 15 1.6.5 Protection Against Gastro-Intestinal Disorders 15 1.6.7 Protection Against Osteoporosis 16 1.7 Changes in Food Consumption Pattern and Future Demand 16 1.8 Food and Nutritional Security 17 1.9 Climate Change and Associated Threat to Agriculture 18 1.10 Millets: As Climate Smart Crops 19 1.11 Future Agriculture: Smart Technologies in Millet Farming 20 1.12 Conclusions 21 References 21 2 The Art and Science of Growing Microgreens 28Sreenivasan Ettammal 2.1 Introduction 28 2.2 Historical Background 29 2.3 Health Benefits of Microgreens 29 2.3.1 Source of Functional Food Components 29 2.3.2 Component of Space Life Support Systems 30 2.3.3 Component of Nutritional Diet of Troops and Residents of High Altitude Regions 30 2.4 Cultivation Practices 30 2.4.1 Species Selection 30 2.4.2 Growing Media and Propagation Felts 30 2.4.3 Growing Process 31 2.5 Quality and Shelf Life 33 2.6 Market Trends 34 2.7 Future Outlook 34 2.8 Conclusions 34 References 35 3 Novel Nutraceuticals From Marine Resources 38Zadia Qamar, Amna Syeda, Javed Ahmed and M. Irfan Qureshi 3.1 Introduction 38 3.2 Marine Microorganisms as a Source of Nutraceuticals 39 3.2.1 Marine Algae 40 3.2.2 Marine Invertebrates 41 3.2.2.1 Sponges 41 3.2.2.2 Crustaceans, Echinoderms and Molluscs 42 3.2.2.3 Marine Fishes 42 3.2.2.4 Marine Actinomycetes 43 3.2.2.5 Marine Fungi 43 3.2.2.6 Marine Bacteria 44 3.3 Classification of Different Nutraceuticals Obtained from Marine Environment 44 3.3.1 Polysaccharides 44 3.3.2 Marine Lipids 45 3.3.3 Natural Pigments from Marine Sources 45 3.3.4 Chitosan and Its Derivatives 48 3.3.5 Proteins and Peptides 48 3.3.6 Minerals, Vitamins and Enzymes 49 3.3.7 Marine Probiotics and Phenolic Compounds 49 3.4 Important Bioactive Metabolites and Their Biological Properties 50 3.5 Current Status of Nutraceuticals in Market 50 3.6 Conclusion and Future Recommendations 51 References 51 4 Bioprospecting of Bioresources: Creating Value From Bioresources 57Deepika Kathuria and Sumit S. Chourasiya 4.1 Introduction 57 4.2 Bioprospecting in Various Industrial Fields 59 4.2.1 Pharmaceutical Industries 59 4.2.1.1 Drugs From Plants 59 4.2.1.2 Drugs From Bugs 61 4.2.1.2.1 Microbes 61 4.2.1.2.2 Enzymes 61 4.2.1.3 Drugs From Aquatics 69 4.3 Chemical Industries 70 4.3.1 Biocatalysis 70 4.4 Bioprospecting in Agriculture 73 4.4.1 Biofertilizers and Biopesticides 73 4.4.2 Bioremediation 74 4.5 Bioprospecting in Beautification/Cosmetics 74 4.6 Bioprospecting in Detergent Industry 78 4.7 Bioprospecting in Textile Industry 80 4.8 Bioprospecting in Paper Industry 81 4.9 Bioprospecting in Food Industry 82 4.9.1 Bioprospecting in Brewing Industry 83 4.10 Diagnostic 83 4.10.1 Application of Enzymes for the Detection of Pyrogens in PharmaceuticalProducts 84 4.10.2 Bioprospecting in Biofuel Production 84 4.11 Conclusions and Future Perspectives 84 References 85 5 Green and Smart Packaging of Food 93Gülden Gökşen, Derya Boyacı and Nick Tucker 5.1 Introduction 93 5.2 Green Packaging in Food 95 5.3 Properties of Green Packaging Materials 95 5.4 Mechanical Properties of Green Packaging Materials 97 5.5 Barrier Properties of Green Packaging 98 5.6 Green Packaging Materials with Active Properties 99 5.7 Biodegradation Mechanisms of Green Packaging 101 5.8 Main Green Food Packaging 104 5.8.1 Poly(lactic Acid) (PLA) 104 5.8.2 Polyhydroxyalkaonate (PHA) 105 5.8.3 Starch-based Materials 106 5.8.4 Cellulose-based Materials 106 5.9 Life Cycle of Green Packaging Materials 107 5.10 Smart Packaging in Food 108 5.11 Indicators for Smart Packaging 110 5.11.1 Time-Temperature Indicator (TTI) 110 5.11.2 Freshness Indicators 111 5.11.3 Packaging Integrity Indicators 112 5.12 Sensor Applications for Smart Packaging 113 5.13 Data Carriers for Smart Packaging 119 5.14 Regulatory Aspects 121 5.15 Conclusion and Future Perspectives 122 References 123 6 Nanosensors: Diagnostic Tools in the Food Industry 133Stephen Rathinaraj Benjamin, Eli José Miranda Ribeiro Junior, Vennilavan Thirumavalavan and Antony De Paula Barbosa 6.1 Introduction 133 6.2 Identification of Foodborne Pathogens and Toxins 134 6.3 Pesticides and Carcinogenic Detection 140 6.3.1 Nitrites-Carcinogenic Detection 141 6.3.2 Mycotoxin Detection 141 6.3.3 Food Packaging 142 6.3.4 Food Freshness Detection 143 6.4 Chemicals and Food Additives Detection 144 6.4.1 Preservatives 144 6.4.2 Dyes 144 6.4.3 Sweeteners 145 6.4.4 Antioxidants 145 6.4.5 Food Allergens 145 6.5 Nano-based Sensors for Smart Packaging 146 6.5.1 Nanobarcodes 147 6.5.2 e-NOSE and e-TONGUE 147 6.5.3 Oxygen Sensors 147 6.5.4 Humidity Sensors 148 6.5.5 Carbon Dioxide (CO2) Sensor 148 6.6 Challenges 149 6.7 Conclusions and Future Perspectives 150 References 150 7 Harnessing Genetic Diversity for Addressing Wheat-based Time Bound Food Security Projections: A Selective Comprehensive Practical Overview 160Abdul Mujeeb-Kazi, Niaz Ali, Ian Dundas, Philip Larkin, Alexey Morghonov, Richard R-C Wang, Francis Ogbonnaya, Hanif Khan, Nasir Saeed, Shabir Wani, Mohammad Sohail Saddiq, Mohammad Jamil, Abdul Aziz Napar, Fatima Khalid, Mahjabeen Tariq, Rumana Keyani, Zeeshan Ali and Sanjaya Rajaram 7.1 The Global Wheat Scenario 162 7.2 Food Security: The Challenge of Feeding Over 9 Billion by 2050 163 7.3 Conventional Wheat Improvement Strategies 165 7.3.1 Breeding Methods 165 7.3.2 Recombination Breeding 166 7.3.3 Pedigree or Line Breeding 167 7.3.4 Bulk Method 168 7.3.5 Single Seed Descent (SSD) Method 168 7.3.6 Backcross Breeding 169 7.3.7 Modified Pedigree Bulk 169 7.3.8 Selected Bulk 170 7.3.9 Multiline Breeding 170 7.3.10 Shuttle Breeding 171 7.3.11 Doubled Haploid 172 7.3.12 Mutation Breeding 173 7.3.13 Hybrid Wheat 175 7.3.14 The XYZ System 176 7.4 Innovative Technologies for Accessing Novel Genetic Diversity 177 7.5 Major Global Locations of Wheat Genetic Diversity 179 7.6 Utilization of Genetic Diversity 179 7.6.1 Wide Crosses: The Historical Build-up 183 7.7 Distribution of Genetic Diversity: Gene Pools, Their Potential Impact and Research Integration for Practicality 185 7.7.1 The Gene Pool Structure 186 7.7.1.1 Primary Gene Pool Species 186 7.7.1.2 The A Genome (Triticum Boeoticum, T. Monococcum, T. Urartu; 2n = 2x = 14, AA) 187 7.7.1.3 The D Genome (Aegilops Tauschii = Goat Grass; 2n = 2x = 14, DD) 187 7.7.1.4 Secondary Gene Pool Species 188 7.7.1.5 Selected Secondary Gene Pool Species Utilization Example 188 7.7.1.6 Tertiary Gene Pool Species 188 7.7.1.7 The Gene Pool Potential Recap 189 7.7.1.8 Conclusion: Transfer Prerequisites Across Gene Pools 191 7.8 Underexplored Areas 191 7.8.1 Land Races: Definitions, General Characteristics and Practicality Potential 191 7.8.2 Wheat Landraces: An Additive Diversity Source 193 7.8.3 Important Collections of Wheat Landraces 194 7.9 Perennial Wheat 198 7.9.1 The Concept of a More Sustainable Perennial Wheat-Like Cereal. Is It Feasible? 198 7.9.1.1 What Benefit/s Would Come? 198 7.9.1.2 Potential Pitfalls 198 7.9.1.3 What Approaches Can Be Conceived? 199 7.9.1.4 What Progress? 200 7.9.1.5 What Lessons? 201 7.9.1.6 Suggested Way Forward? 7.9.2 Genetic Engineering for Wheat Improvement Focused on a Few Major Food Security Aspects 204 7.9.2.1 Tissue Culture and Transformation of Wheat 204 7.9.2.2 Production of Genetically-Modified Wheat 205 7.9.2.3 CRISPR/Cas9 Genome Editing in Wheat 205 7.9.2.4 Potential Traits for Genetic Improvement of Wheat Through Biotechnology 206 7.9.2.5 Yield Potential 206 7.9.2.6 Climate Change 207 7.9.2.7 Drought 207 7.9.2.8 Salinity 207 7.9.2.9 Heat 208 7.10 Historical Non-Conventional Trends for Exploiting Wheat’s Genetic Resources 208 7.10.1 Pre-1900 208 7.10.2 1901–1920 209 7.10.3 1921–1930 210 7.10.4 1931–1950 210 7.10.5 The Post-1950 Era: Preamble 211 7.10.6 Homoeologous Pairing 212 7.10.7 Isolation of Homoeologous Recombinants 213 7.10.8 Intergeneric Hybridization Steps for Wheat/Alien Crossing 214 7.10.8.1 Embryo Extraction and Handling 217 7.10.8.2 Pre-Breeding Protocol 218 7.10.8.3 Development of Genetic Stocks 219 7.10.8.4 Establishing a Living Herbarium 219 7.10.9 Interspecific Hybridization 219 7.10.10 Additive Durum Wheat Improvement 219 7.10.10.1 The Parental Choice 221 7.10.10.2 Shortening the Breeding Cycle by Inducing Homozygosity in Desired Early Breeding Generations 222 7.10.10.3 The Integration of Molecular Development Options for Efficiency and Precision 223 7.11 Alleviating Wheat Productivity Constraints via New Genetic Variation 224 7.11.1 Biotic Constraints 224 7.11.2 Insect Resistance 225 7.11.3 Root Diseases 226 7.11.4 Abiotic Stresses 226 7.11.5 Grain Yield 227 7.11.6 Bio-Fortification 228 7.11.7 Future Directions and Strategies 228 7.12 Accruing Potental Practical Benefits 230 7.13 Summary of the Practical Potential Benefits 236 7.14 The Role of Genomics Information Including Molecular Markers in Wheat 237 7.15 The Way Forward and Wrap-Up 248 7.16 Concerns 249 7.17 Conclusions 250 7.18 Some Perceptions 252 References 253 Part II: Bioresource and Future Energy Security 289 8 Waste-to-Energy: Potential of Biofuels Production from Sawdust as a Pathway to Sustainable Energy Development 291Oyebanji Joseph Adewumi, Oyedepo Sunday Olayinka, Kilanko Oluwaseun and Dunmade Israel Sunday 8.1 Introduction 291 8.2 Overview of Potential WTE Technologies for Biomass Wastes 293 8.2.1 Thermo-Chemical Conversion Technologies 293 8.2.1.1 Gasification 294 8.2.1.2 Pyrolysis 294 8.2.1.3 Liquefaction 295 8.3 Biochemical Conversion Technologies 295 8.4 Potential Feedstocks for Waste-to-Energy 296 8.4.1 Agricultural Residues 296 8.4.2 Animal Waste 296 8.4.3 Forestry Residues 296 8.4.4 Industrial Wastes 296 8.4.5 Municipal Solid Waste (MSW) 297 8.4.6 Black Liquor 297 8.5 Waste-to-Energy and Sustainable Energy Development 297 8.6 Challenges and Future Prospects of Waste-to-Energy Technologies 298 8.7 Case Study: Application of Fast Pyrolysis for Conversion of Sawdust to Bio-Oil 299 8.7.1 Samples Collection and Experimental Analysis 299 8.7.2 Instrumentation and Experimental Set-up 299 8.7.3 GCMS Analysis 299 8.7.4 Chemical and Physical Composition of Biofuel Yield 300 8.7.5 Characterization of Bio-Oil Yield from Sawdust Samples 301 8.8 Economic and Environmental Benefits of Biofuel 304 8.8.1 Economics Benefits 304 8.8.2 Environmental Benefits of Biofuel 304 8.9 Conclusion and Recommendations 304 References 305 9 Biogas Production and Processing from Various Organic Wastes in Anaerobic Digesters and Landfills 310Setareh Heidari, David A. Wood, Birendra K. Rajan and Ahmad Fauzi Ismail 9.1 Introduction 310 9.2 Urban Waste as a Raw Material for Biogas Production 311 9.2.1 Independent-Source Organic Waste 311 9.2.2 Sewage Sludge 312 9.3 Biogas Feedstock Properties 313 9.3.1 Suitability and Availability 313 9.3.2 Digestibility 318 9.3.3 Impurities with Digester-Disrupting Effects 318 9.3.4 Feedstocks Acting as AD Biogas Boosters 318 9.4 Biogas Production Technology Applied to Landfills 319 9.4.1 Anaerobic Digester Pre-Treatments 321 9.4.2 Digester Design and Process Optimization 322 9.4.3 Hydrolysis Enhancements 322 9.4.4 Bacterial Clean-up of AD Digester Effluent 323 9.4.5 Additives to Enhance Methane Yield 324 9.4.6 Biogas Upgrading Technologies 324 9.4.6.1 Carbon Dioxide Removal Technologies 324 9.4.7 Hydrogen Sulfide and Ammonia Removal 326 9.4.8 Siloxane Removal 326 9.5 Conclusions 326 References 327 10 Extremophiles as Gold Mines for Bioprospecting 332Sheikh Tanveer Salam, Mukhtar Ahmad Malik and Tanveer Bilal Pirzadah 10.1 Introduction 332 10.2 Bioprospecting of Extremophiles 333 10.3 Bioprospecting of Thermophiles 338 10.4 Bioprospecting of Acidophiles 338 10.5 Bioprospecting of Psychrophiles 339 10.6 Bioprospecting of Halophiles 339 10.7 Bioprospecting of Metallophiles 339 10.8 Conclusion and Future Perspective 340 References 340 Part III: Bioresource Technology: Solution to Sustainable Environment and Management Policies 345 11 Algal-based Membrane Bioreactor for Wastewater Treatment 347Setareh Heidari, David A. Wood and Ahmad Fauzi Ismail 11.1 Introduction 347 11.2 Algal Treatment System: Requirements and Complications 349 11.3 Elements of Microalgae Cultivation 350 11.4 Membranes and Their Application in Water and Wastewater Treatments 351 11.5 Algal Membrane Photobioreactors 353 11.6 Factors Affecting the Performance of Membrane Photobioreactors 356 11.6.1 Operating Factors 356 11.6.1.1 Temperature 356 11.6.2.2 Acidity-Alkalinity (Ph) 356 11.6.3.3 Flux and Permeate Flux Through the Reactors 356 11.6.4.4 Hydraulic and Solids Retention Time 356 11.6.5.5 Lighting 357 11.6.6.6 Aeration 357 11.7 Biomass Properties Impacting MPBR Performance 357 11.7.1 Microorganisms 357 11.7.2 Wastewater Properties 358 11.8 Challenges and Limitations 358 11.9 Future Directions for Algal-based Membrane Bioreactors 11.10 Conclusions 360 References 361 12 Engineering Plants for Metal Tolerance and Accumulation 373Fernanda Maria Policarpo Tonelli, Flávia Cristina Policarpo Tonelli, Moline Severino Lemos, Helon Guimarães Cordeiro and Danilo Roberto Carvalho Ferreira 12.1 Introduction 373 12.2 Metals’ Bioremediation 374 12.2.1 Metal Phytoremediation 376 12.2.2 Non-Target Specific Engineered Plants to Metal Phytoremediation 377 12.2.3 Target Specific Genomic Engineering Technique to Enhance Plants Metal Tolerance and Accumulation 380 12.2.4 Important Methodologies to Engineer Plants to Metals Phytoremediation 383 12.3 Omics as Tools to Elucidate Important Genes to Plants Engineering 384 12.4 Conclusion 387 12.5 Future Perspectives 387 References 388 13 Recent Advances in Enzymatic Membranes and Their Sustainable Applications Across Industry 399Setareh Heidari, David A. Wood and Ahmad Fauzi Ismail 13.1 Introduction 399 13.2 Enzymes 401 13.3 Global Demand for Commercial Enzymes 403 13.4 Membrane Technology 405 13.5 Fouling-Type Immobilization Membranes 407 13.6 Physical Procedures that Immobilize Enzyme in/on Membranes 407 13.7 Covalent Bonds that Immobilize Enzymes in/on Membranes 407 13.7.1 Amino Groups that Modify Membranes 408 13.7.2 Carboxylic Groups that Modify Membranes 408 13.7.3 Epoxy Groups that Modify Membranes 408 13.7.4 Azido Groups that Modify Membranes 409 13.8 Cross-linkage Procedures 409 13.9 Applications of Enzymatic Membrane Reactors 409 13.9.1 Treatment of Milk or Cheese Whey 409 13.9.2 Treatments of Animal, Plant, and Waste Oils and Fats 410 13.9.3 Pharmaceutical Production Employing Biocatalytic Membrane Reactors 410 13.9.4 Biocatalytic-Membrane Reactors for Biomedical Applications 411 13.9.5 Biocatalytic-Membrane Reactors for Agricultural Applications 411 13.9.6 Biocatalytic-Membrane Reactors for Waste-Water Treatment 411 13.10 Limitations, Challenges and Solution for EMR Applications 412 13.11 Conclusions 414 References 415 14 Use and Manufacture of Biopesticides and Biofertilizers in Latin America 424Luis Jesús Castillo-Pérez, Juan José Maldonado Miranda and Candy Carranza-Álvarez 14.1 Introduction 424 14.2 Current Problems of Pesticides and Fertilizers in Latin America 425 14.3 Manufacture and Use of Biopesticides and Biofertilizers in Latin America 426 14.4 Manufacture of A Natural Repellent: A Case Study 430 14.5 Biotechnological Interventions in Biopesticide Synthesis 433 14.6 Biofertilizers Relevance and Plant Tolerance to Abiotic/Biotic Stress 433 14.7 Conclusions 436 References 436 15 Carbon Sequestration Alternatives for Mitigating the Accumulation of Greenhouse Gases in the Atmosphere 443Erfan Sadatshojaei, Setareh Heidari, Zahra Edraki, David A. Wood and Ahmad Fauzi Ismail 15.1 Introduction 443 15.2 Impact of Greenhouse Gases 444 15.2.1 The Natural Greenhouse Impacts 444 15.2.2 Anthropogenic Greenhouse Impacts 445 15.3 Soil’s Role in the Sequestration of Carbon 446 15.3.1 Organic Carbon Sequestration 446 15.3.2 Inorganic Carbon Sequestration in Soils 449 15.4 Terrestrial Carbon Sequestration 450 15.4.1 Global Forest Management 450 15.4.1.1 Improving Agricultural Practices 452 15.4.1.2 Improving Biofuel Production Processes 453 15.5 Carbon Sequestration into Sub-Surface Geological Reservoirs 454 15.6 Oceanic Carbon Sequestration 456 15.7 Conclusions 457 References 458 16 Nanotechnology for Future Sustainable Plant Production Under Changing Environmental Conditions 466Ayesha Tahir, Jun Kang, Jaffer Ali, Ameer Bibi and Shabbar Abbas 16.1 Introduction 466 16.2 Nanotechnology and Synthesis of Nanomaterials 467 16.2.1 Chemical Methods 467 16.2.2 Physical Methods 468 16.2.3 Biological Methods (Green Synthesis) 468 16.2.3.1 Plant Extract-based Synthesis of Nanomaterials 468 16.2.3.2 Microorganism-based Synthesis of Nanomaterials 469 16.3 Potential Applications of Nanotechnology in Agriculture for Climate Resilient Crops 470 16.3.1 Nanotechnology and Efficient Use of Input Resources 470 16.3.1.1 Water Use Efficiency Enhancement 470 16.3.1.2 Light Use Efficiency Enhancement 471 16.3.1.3 Nutrient Use Efficiency Enhancement 471 16.3.2 Nanomaterials and Plant Growth Enhancement 472 16.3.2.1 Germination and Vigor Enhancement 472 16.3.3 Nanoparticles to Mitigate Biotic Stresses 473 16.3.3.1 Nano-Pesticides 473 16.3.3.2 Nano-Fungicides 473 16.3.4 Nanomaterials to Mitigate Abiotic Stresses 474 16.3.4.1 Nanoparticles to Mitigate Drought Stress 474 16.3.4.2 Nanoparticles to Mitigate Metal Stress 474 16.3.4.3 Nanoparticles to Mitigate Salinity Stress 476 16.3.4.4 Nanoparticles to Mitigate Flooding Stress 477 16.3.4.5 Nanoparticles to Mitigate Heat Stress 477 16.3.4.6 Nanoparticles to Mitigate Cold Stress 477 16.4 Advances in Nanotechnology 478 16.4.1 Nanotechnology in Tissue Culture 478 16.4.2 NPs in Genome Editing 479 16.4.3 Nanosensors/Smart Plant Sensors 480 16.5 Conclusions and Future Prospects 481 References 482 17 Nanoscience: A Boon for Reviving Agriculture 493Afrozah Hassan, Shabana Gulzar, Hanan Javid and Irshad Ahmad Nawchoo 17.1 Introduction 493 17.2 Agriculture: A Growing Need 494 17.2.1 Advanced Agriculture System Through Nanoscience 494 17.2.2 Nanofertilizers for Agriculture 495 17.3 Nano Herbicides and Agriculture 496 17.4 Nanotechnology Leading to Sustainable Agriculture 497 17.5 Conclusion 499 References 499 18 Profitability and Economics Analysis of Bioresource Management 504Ghulam Mustafa 18.1 Introduction 504 18.2 Bioeconomy 504 18.3 Profitability Analysis of Bioresource-based Business 505 18.3.1 Short Rotation Cultivation (SRC) 506 18.3.2 Ecotourism 507 18.3.3 District Heating 507 18.3.4 Aquatic Biorefinery 508 18.4 Food Waste to Bioresource Businesses and Their Efficacies 509 18.4.1 Biofertilizer and Biogas Production 509 18.4.2 Biomethane 509 18.4.3 Bioethanol Fermentation 510 18.5 Bioresources for Risk Prevention and Poverty Alleviation 512 18.6 Conclusion 513 References 513 Index 517

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Book SynopsisMicrobiomics and Sustainable Crop Production Microbiomics and Sustainable Crop Production presents an overview of the current state of the art in microbiome research, discussing many new technologies and approaches in order to bridge knowledge gaps between field and lab experimental systems. New and emerging strategies to improve the survival and activity of microbial inoculants are covered, including the use of selected indigenous microbes, optimizing microbial delivery methods, and taking advantage of modern gene editing tools to engineer microbial inoculants. The two highly qualified authors address new molecular tools and powerful biotechnological advances, providing readers with knowledge of the complex chemical and biological interactions that occur in the rhizosphere and ensuring that strategies to engineer the rhizosphere are safe, beneficial to productivity, and result in improvements to the sustainability of agricultural systems. The relationship between phyllosphere microbial communities and functional traits of plants is also explored. Finally, approaches and priority areas for future research on phyllosphere microbiology are suggested. Topics covered in this comprehensive resource include: Transmission modes of bacteria and fungi and the nature of their interactions in the endosphere Characteristics of core microbiomes', which may be deployed to organize otherwise uncontrollable dynamics of resident microbiomes Model microbiome-plant systems, as well as the stability, resilience, and assembly of agricultural microbiomes Engineering and management of agricultural microbiomes for improving crop health, including reasons to modify plant microbiomes Microbiome research in the omics era and new efforts and challenges in assigning functions to microbes For students of plant biotechnology, agricultural sciences, and agricultural engineering, along with researchers working in related fields, Microbiomics and Sustainable Crop Production is an important resource to understand many complex modern ideas related to the subject and how they can be applied to practical applications.Table of ContentsPreface xi About the Authors xii 1 Agricultural Microbiomes: Functional and Mechanistic Aspects 1 1.1 Introduction 2 1.2 Model Microbiome--Plant Systems 2 1.3 Stability, Resilience, and Assembly of Agricultural Microbiomes 11 1.4 Core Plant Microbiome and Metagenome 13 1.5 Interactions Among the Microbes, Environment, and Management 14 1.6 Microbiome Innovation in Agriculture: Insect Pest Management 21 2 Engineering and Management of Agricultural Microbiomes for Improving Crop Health 66 2.1 Why to Modify Plant Microbiome? 67 2.2 Methods for Detecting Endophytes Within the Plant 69 2.3 Engineering of the Plant Microbiome 79 2.4 In Situ Harnessing of Agricultural Microbiome 82 2.5 Future Perspective of Agricultural Microbiome Engineering 86 3 Approaches and Challenges in Agricultural Microbiome Research 97 3.1 Microbiome Research in the Omics Era 97 3.2 New Efforts and Challenges in Assigning Function to Microbes 99 3.3 Characterization of Complex Microbial Communities 101 3.4 AdvancedFundamental Research on Microbe--Microbe and Plant--Microbe Interactions : Bridging the Lab--Field Gap 102 4 Perceptive of Rhizosphere Microbiome 111 4.1 Introduction 112 4.2 Multiple Levels of Selection in the Plant Rhizosphere 113 4.3 Engineering Microbial Populations and Plant--Microbe Interactions 127 4.4 Emerging Approaches in Rhizoremediation 128 4.5 Heritability of Rhizosphere Microbiome 137 4.6 Future Course of Orientations 139 5 Microbial Communities in Phyllosphere 154 5.1 Introduction 154 5.2 Diversity of Microbes in Phyllospheric Environment 156 5.3 Microbial Adaptation to the Phyllosphere 160 5.4 Relationship between Phyllosphere Microbial Communities and Functional Traits of Plants 163 5.5 Metabolic Dynamics of Phyllosphere Microbiota 166 5.6 Impact of Phyllospheric Microorganisms on Plant--Plant, Plant--Insect, and Plant Atmosphere Chemical Exchanges 167 5.7 Quorum Sensing in Phyllosphere 169 5.8 Applications for Phyllosphere Microbiology 171 6 Endosphere and Endophyte Communities 193 6.1 Reproduction and Transmission Modes of Microbes 194 6.2 Vertical Transmission 196 6.3 Endophyte Genomes and Metagenomes 207 6.4 Bacteria and Fungi in Mixed Biofilms in Plants 213 6.5 Conclusion and Future Perspectives 216 7 Core Microbiomes: For Sustainable Agroecosystems 240 7.1 Core Microbiome for Agriculture: A Taxonomic and Functional Aspect 241 7.2 Core Microorganisms and Priority Effects in Initial Assembly 249 7.3 Informatics of Microbial Networks 255 7.4 Designing Core Microbiomes 257 7.5 Management of Agroecosystems with Core Microbiomes 260 8 Microbiome Mediated: Stress Alleviation in Agroecosystems 272 8.1 Effect of Biotic and Abiotic Stresses on Plants 273 8.2 Molecular and Physiological Responses of Plants Against Stresses 285 8.3 Microbiome Mediated Mitigation of Stress Conditions 288 8.4 Multi-Omics Strategies to Address Stress Alleviation 293 References 303 Index 320

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Book SynopsisSustainable Agriculture Systems and Technologies A robust treatment of traditional and new techniques in sustainable agriculture In Sustainable Agriculture Systems and Technologies, a team of distinguished researchers delivers an up-to-date and comprehensive exploration of sustainable agriculture and its relationship to the drivers of climate change. Along with robust examinations of food security and the agrarian livelihood, the book covers the impact of climate change and variability on agriculture, water management in agricultural systems, and precision agriculture. This book represents a significant contribution to the scientific understanding of the application of technologies that address food insecurity and climate change through sustainable productivity, system diversification, irrigation practices, crop modeling, data analytics, and agricultural policy. It also explores the risks and benefits of different agricultural systems under changing climate scenarios. The book also ofTable of ContentsList of Contributors viii Preface xiv About the Editors xvi Foreword 1 xix Foreword 2 xxi Section 1 Food Security and Agrarian Livelihood 1 1 Agriculture and Nutritional Security in India 3Shubhi Patel, Anwesha Dey, Rakesh Singh, and Ramesh Chand 2 Diversification for Restoration of Ecosystems and Sustainable Livelihood 21Sanjay S. Rathore, Kapila Shekhawat, R.K. Singh, S. Babu, and V.K. Singh 3 Impact of Total Mixed Ration on Performance of Heifers and Homemade Concentrate Feeding on Milk Yield in Dairy Animals 37A. Dey, B.P. Bhatt, and J.J. Gupta 4 Multifaceted Impact of Lockdown During COVID-19 on Food Security and Smallholder Agricultural Systems 49Aishwarya, Meenu Rani, Bhagwan Singh Chaudhary, Bharat Lal, Rajiv Nandan, and Pavan Kumar Section 2 Climate Change and Agriculture 63 5 Crop Diversification: An Approach for Productive and Climate-Resilient Production System 65Rakesh Kumar, Bal Krishna, Prem K. Sundaram, Narendra Kumawat, Pawan Jeet, and Anil Kumar Singh 6 Impacts of Climate Variability on Food Security Dimensions in Indonesia: Reference from the Nusa Tenggara Timur Province 81Boubacar Siddighi Balde, Martiwi Diah Setiawati, I. Wayan Nampa, and Mohamed Esham 7 Knowledge-Intensive Livestock Resource Management in a Changing Environment 117Avijit Haldar, Indranil Samanta, and Amlan Kumar Patra 8 Aquaculture Resources and Practices in a Changing Environment 169Shib Kinkar Das, Amit Mandal, and Sachin Onkar Khairnar Section 3 Water Management in Agricultural Systems 201 9 An Approach to Understand Conservation Agriculture 203Anwesha Dey, Shubhi Patel, and H.P. Singh 10 Quality of Irrigation Water for Sustainable Agriculture Development in India 224Bharat Lal, Abhishek Kumar Shukla, Pavan Kumar, and Susheel Kumar Singh 11 Agricultural Water Footprint and Precision Management 251V.K. Singh, G.A. Rajanna, V. Paramesha, and Pravin Kumar Upadhyay 12 Drip Fertigation for Enhancing Crop Yield, Nutrient Uptake, Nutrient, and Water Use Efficiency 267V. Paramesha, G.A. Rajanna, Parveen Kumar, M.S. Sannagoudar, and H.M. Halli Section 4 Precision Agriculture 279 13 Sustainable Agriculture Systems and Technologies 281Amit K. Singh, Avijit Ghosh, Manjanagouda S. Sannagoudar, R.V. Kumar, Sunil Kumar, Prashant Deo Singh, and Safik Ahamad 14 Geoinformatics,Artificial Intelligence, Sensor Technology, Big Data: Emerging Modern Tools for Sustainable Agriculture 295Abhishek Singh, Riya Mehrotra, Vishnu D. Rajput, Pavel Dmitriev, Anil Kumar Singh, Pradeep Kumar, Ram Sewak Tomar, Omkar Singh, and Awani Kumar Singh 15 Investigation of the Relationship Between NDVI Index, Soil Moisture, and Precipitation Data Using Satellite Images 314Shilan Felegari, Alireza Sharifi, Kamran Moravej, Ahmad Golchin, and Aqil Tariq 16 Artificial Machine Learning–Based Classification of Land Cover and Crop Types Using Sentinel-2A Imagery 326Ram Kumar Singh, Pavan Kumar, Manoj Kumar, Keshav Tyagi, and Harshi Jain 17 Geoinformatics and Nanotechnological Approaches for Coping Up Abiotic and Biotic Stress in Crop Plants 337Abhishek Singh, Vishnu D. Rajput, Sapna Rawat, Ragini Sharma, Anil Kumar Singh, Pradeep Kumar, Awani Kumar Singh, Tatiana Minkina, Rudra Pratap Singh, and Shashank Singh Index 360

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Book SynopsisTable of ContentsList of Contributors xix Preface xxix Editor Biographies xxxi 1 Plant Response and Tolerance to Heavy Metal Toxicity: An Overview of Chemical Biology, Omics Studies, and Genetic Engineering 1 Lovely Mahawar, Sakshi Pandey, Aparna Pandey, and Sheo Mohan Prasad 1.1 Introduction 1 1.2 Plant–Metal Interaction 2 1.3 Effect of Heavy Metals on Plants 3 1.3.1 Morphoanatomical Responses 3 1.3.2 Physiological Responses 8 1.3.3 Biochemical Responses 8 1.3.4 Molecular Responses 9 1.4 Mechanisms to Tolerate Heavy Metal Toxicity 10 1.4.1 Avoidance 10 1.4.1.1 Mycorrhizal Association 10 1.4.1.2 Root Exudates 12 1.4.2 Sequestration 12 1.5 Important Strategies for the Enhancement of Metal Tolerance 15 1.5.1 Omics 15 1.5.1.1 Genomics 15 1.5.1.2 Transcriptomics 15 1.5.1.3 Proteomics 17 1.5.1.4 Metabolomics 17 1.5.1.5 Ionomics 18 1.5.1.6 miRNAomics 19 1.5.1.7 Metallomics 19 1.5.2 Genetic Engineering 20 1.5.2.1 CRISPR Technology 20 1.5.2.2 Plastid Transformation 21 1.5.2.3 Gene Silencing 22 1.6 Conclusion and Future Prospects 22 References 23 2 Advanced Techniques in Omics Research in Relation to Heavy Metal/Metalloid Toxicity and Tolerance in Plants 35 Ali Raza, Shanza Bashir , Hajar Salehi , Monica Jamla, Sidra Charagh, Abdolkarim Chehregani Rad, and Mohammad Anwar Hossain 2.1 Introduction 35 2.2 An Overview of Plant Responses to Heavy Metal Toxicity 36 2.3 How the Integration of Multi-omics Data Sets Helps in Studying the Heavy Metal Stress Responses and Tolerance Mechanisms? 39 2.3.1 The Contribution of State-of-the-Art Genomics-Assisted Breeding 39 2.3.1.1 Quantitative Trait Locus (QTL) Mapping 39 2.3.1.2 Genome-Wide Association Studies 41 2.3.2 Transcriptomics 42 2.3.3 Proteomics 44 2.3.4 Metabolomics 46 2.3.5 miRNAomics 47 2.3.6 Phenomics 49 2.4 Conclusion and Perspectives 50 References 50 3 Heavy Metals/Metalloids in Food Crops and Their Implications for Human Health 59 Shihab Uddin, Hasina Afroz, Mahmud Hossain, Jessica Briffa, Renald Blundell, and Md. Rafiqul Islam 3.1 Introduction 59 3.2 Arsenic 60 3.2.1 Sources and Forms 60 3.2.2 Food Chain Contamination 62 3.2.3 Pharmacokinetic Processes 62 3.2.4 Toxicology Processes 62 3.2.5 Remedial Options 63 3.3 Cadmium 63 3.3.1 Sources and Forms 64 3.3.2 Food Chain Contamination 64 3.3.3 Pharmacokinetic Processes 66 3.3.4 Toxicology Processes 66 3.3.5 Remedial Options 67 3.4 Lead 67 3.4.1 Sources and Forms 68 3.4.2 Food Chain Contamination 68 3.4.3 Pharmacokinetic Processes 68 3.4.4 Toxicology Processes 70 3.4.5 Remedial Options 71 3.5 Chromium 72 3.5.1 Sources and Forms 72 3.5.2 Food Chain Contamination 74 3.5.3 Pharmacokinetic Processes 74 3.5.4 Toxicology Processes 74 3.5.5 Remedial Options 75 3.6 Mercury 76 3.6.1 Sources and Forms 76 3.6.2 Food Chain Contamination 77 3.6.3 Pharmacokinetic Processes 79 3.6.4 Toxicology Processes 79 3.6.5 Remedial Options 80 3.7 Conclusions 81 References 81 4 Aluminum Stress Tolerance in Plants: Insights from Omics Approaches 87 Richa Srivastava, Ayan Sadhukhan, and Hiroyuki Koyama 4.1 Introduction 87 4.2 Exploration of Al Tolerance QTLs 89 4.3 Unraveling the Genetic Architecture of Al Tolerance from Natural Variation 91 4.4 Identification of Novel Al Tolerance Genes Through Genome-Wide Association Studies 91 4.5 Exploring Expression Level Polymorphisms to Identify Upstream Al Signaling 92 4.6 Comparative Transcriptome Analyses Identify Novel Al Tolerance Genes 93 4.7 Identification of Al Tolerance Genes from Proteomics 95 4.8 Conclusion and Future Perspectives 99 References 99 5 Breeding Approaches for Aluminum Toxicity Tolerance in Rice and Wheat 105 Buu Chi Bui and Lang Thi Nguyen 5.1 Introduction 105 5.2 Plant Signaling 107 5.3 Rice Genetic Mapping 107 5.3.1 Linkage Mapping 107 5.3.2 Association Mapping 108 5.4 Root Transcriptome 109 5.5 Wheat Genetic Mapping 114 5.5.1 Wheat MATE Gene Family 116 5.6 Wheat Proteomics 117 5.7 Conclusion 118 References 118 6 Chromium Toxicity and Tolerance in Plants: Insights from Omics Studies 125 Sonali Dubey, Manju Shri, and Debasis Chakrabarty 6.1 Introduction 125 6.2 Chromium Sources and Bioavailability 126 6.3 Chromium Uptake, Translocation, and Sub-cellular Distribution in plants 127 6.4 Detoxification Mechanisms for Cr 129 6.5 Omics Approaches Used by Plants to Combat Cr Toxicity 130 6.5.1 Transcriptomics 130 6.5.2 Chromium-Induced miRNAs in Plants 132 6.5.3 Metabolomics 133 6.5.4 Proteomics 133 6.6 Phytoremediation of Cr Metal by Plants 134 6.6.1 Phytoremediation Approach for Cr Detoxification 134 6.6.2 Other Strategies Involved in Cr Remediation 135 6.6.3 Phytostabilization/Phytoextraction for Cr Decontamination 136 6.7 Conclusion 136 References 136 7 Manganese Toxicity and Tolerance in Photosynthetic Organisms and Breeding Strategy for Improving Manganese Tolerance in Crop Plants: Physiological and Omics Approach Perspectives 141 Daisuke Takagi 7.1 Introduction 141 7.2 The Change in Mn Availability Within the Soil 143 7.3 Why Should We Consider the Occurrence of Mn Toxicity in Plants? Possible Threats of Mn Toxicity in Agricultural Land 144 7.4 The History of Mn Toxicity 146 7.5 The Features of Mn Toxicity in Terrestrial Plants and Possible Molecular Mechanisms 147 7.5.1 The Mechanisms of Emergence of Brownish Patchy Spots in Leaves: The Apoplastic Mn Toxicity 147 7.5.2 The Mechanisms of Foliar Chlorosis Under Excess Mn: Symplastic Mn Toxicity 150 7.6 Breeding Strategy for Overcoming the Future Threat of Excess Mn Conditions 154 7.6.1 Limiting Mn Absorption from Soil to Root 155 7.6.2 Sequestration of Mn from Cytosol to the Vacuole or Apoplast 156 7.6.3 Maintenance of Auxin Homeostasis 157 7.6.4 The Reinforcement of Silicon Uptake and Its Distribution 157 7.7 Conclusion and Future Prospects 158 Acknowledgments 158 References 158 8 Iron Excess Toxicity and Tolerance in Crop Plants: Insights from Omics Studies 169 May Sann Aung and Hiroshi Masuda 8.1 Iron Uptake and Translocation Mechanism in Plants 169 8.1.1 Importance of Iron in Living Organisms 169 8.1.2 Fe Acquisition Systems in Plants 170 8.1.3 Fe Translocation Mechanisms in Plants 171 8.2 Fe Excess Toxicity in Plants 171 8.2.1 Fe Excess Toxicity in Global Agriculture 171 8.2.2 Causes of Fe Excess Toxicity in Soils and Its Interaction with Plants 172 8.2.2.1 State of Fe in Soils and Soil pH Effects on Fe Excess Toxicity 172 8.2.2.2 Soil Improvement Methods to Ameliorate Fe Excess Toxicity 173 8.2.2.3 Soil Water and Drainage Effects on Fe Excess Toxicity 173 8.2.3 Effects of Fe Excess Toxicity on Plant Growth 174 8.3 Crop Defense Mechanisms Against Excess Fe and Genes Regulating Fe Excess 175 8.3.1 Defense I: Fe Exclusion from Roots 175 8.3.1.1 Genes Involved in Defense I 176 8.3.2 Defense II: Fe Retention in Roots and Suppression of Fe Translocation to Shoots 177 8.3.3 Defense III: Fe Compartmentalization in Shoots 177 8.3.3.1 Genes Involved in Defense II and IIi 178 8.3.3.2 Role of YSL4 and YSL6 Transporters in Preventing Fe Excess in Early Plant Development 179 8.3.4 Defense IV: ROS Detoxification 179 8.3.4.1 Genes Involved in Defense IV 180 8.3.4.2 GLY1 as a Detoxifying Agent 180 8.4 Research Outlook on Fe Excess Response of Plants 180 8.4.1 Regulation of Fe homeostasis in Plants in Response to Fe Excess Stress 180 8.4.2 Transcription Factors 181 8.4.3 Cis-Regulatory Elements 182 8.5 Conclusion and Future Prospects 183 Acknowledgments 183 Author Contributions 183 Disclosures 183 References 183 9 Molecular Breeding for Iron Toxicity Tolerance in Rice (Oryza sativa L.) 191 Dorothy A. Onyango, Mathew M. Dida, Khady N. Drame, Benson O. Nyongesa, and Kayode A. Sanni 9.1 Introduction 191 9.2 Role of Iron in Plants and Rice 192 9.3 Iron Toxicity and Its Effects on Rice 192 9.4 Iron Toxicity Tolerance Mechanisms in Rice Plants 193 9.4.1 Fe Exclusion from Roots 193 9.4.2 Fe Retention in Roots and Suppression of Fe Translocation to Shoots 194 9.4.3 Fe Compartmentalization in Shoots 194 9.4.4 ROS Detoxification 195 9.4.5 Candidate Genes Involved in the Mechanisms of Fe Toxicity 196 9.4.6 Genetic Variants for Iron Toxicity Tolerance in Rice Germplasm 197 9.5 Molecular Breeding for Fe Toxicity Tolerance in Rice 197 9.6 Conclusion 200 References 202 10 Cobalt Induced Toxicity and Tolerance in Plants: Insights from Omics Approaches 207 Abdul Salam, Muhammad Siddique Afridi, Ali Raza Khan, Wardah Azhar, Yang Shuaiqi, Zaid Ulhassan, Jiaxuan Qi, Nu Xuo, Yang Chunyan, Nana Chen, and Yinbo Gan 10.1 Introduction 207 10.2 Plant Response to Cobalt Stress 208 10.2.1 Uptake and Translocation of Cobalt in Plants 209 10.3 Cobalt-Induced ROS Generation and Their Damaging Effects 211 10.3.1 ROS-Induced Lipid Peroxidation 211 10.3.2 ROS-Induced Damage to Genetic Material 212 10.4 Cobalt-Induced Plant Antioxidant Defense System 213 10.4.1 Enzymatic Antioxidants 213 10.4.1.1 Superoxide Dismutase (SOD) 213 10.4.1.2 Catalases (CAT) 213 10.4.1.3 Glutathione Peroxidases (GPX) 214 10.4.1.4 Glutathione Reductase (GR) 214 10.4.2 Nonenzymatic Antioxidants 215 10.4.2.1 Ascorbic Acid 215 10.4.2.2 Tocopherols 215 10.4.2.3 Reduced Glutathione (GSH) 216 10.5 Omics Approaches in Cobalt Stress Tolerance 216 10.5.1 Transcriptomic 216 10.5.2 Metabolomics 218 10.5.3 Proteomics 219 10.6 Conclusion and Future Prospects 220 Acknowledgments 221 References 221 11 Nickel Toxicity and Tolerance in Plants 231 Sondes Helaoui, Marouane Mkhinini, Iteb Boughattas, Noureddine Bousserrhine, and Mohamed Banni 11.1 Introduction 231 11.2 Sources of Ni 232 11.2.1 Natural Sources of Ni 232 11.2.2 Anthropogenic Sources of Ni 233 11.3 Role of Ni in Plants 233 11.4 Ni Uptake and Accumulation in Plants 233 11.5 Ni Toxicity in Plants 234 11.5.1 Growth Inhibition 234 11.5.2 Photosynthesis Inhibition of Ni 236 11.5.3 Induction of Oxidative Stress 236 11.6 Tolerance Mechanisms 237 11.7 Omics Approaches in Ni Stress Tolerance 238 11.7.1 Transcriptomics 238 11.7.2 Proteomics 239 11.7.3 Metabolomics 240 11.8 Conclusion 240 References 241 12 Copper Toxicity and Tolerance in Plants: Insights from Omics Studies 251 Moreira A, Moraes LAC, Delfim JJ, and Moreti LG 12.1 Introduction 251 12.2 Copper in Plants 253 12.2.1 Functions of Copper 253 12.2.2 Uptake, Transport, Distribution, and Remobilization Mechanisms 255 12.2.3 Deficient, Sufficient, and Toxic Levels of Copper in Plants 255 12.2.4 Copper Sources: Fertilizers and Fungicides 256 12.3 Omics Approaches for Cu Responses and Tolerance in Plants 259 12.3.1 Genomics 259 12.3.2 Transcriptomics 259 12.3.3 Proteomics 261 12.3.4 Metabolomics 263 12.3.5 miRNAomics 264 12.4 Concluding Remarks 266 Acknowledgments 266 References 267 13 Zinc Toxicity and Tolerance in Plants: Insights from Omics Studies 275 Imran Haider Shamsi, Qichun Zhang, Zhengxin Ma, Sibgha Noreen, Muhammad Salim Akhter, Ummar Iqbal, Muhammad Faheem Adil, Muhammad Fazal Karim, and Najeeb Ullah 13.1 Introduction 275 13.1.1 Zinc Uptake and Translocation Mechanisms in Plants 275 13.1.2 Transporters and Metal-Binding Compounds Involved in Zinc Homeostasis 277 13.2 Impact of Excess Zinc on Physio-genetics Aspects of Plants 277 13.2.1 Effect of Zinc Toxicity on Seed Germination and Growth of Plants 278 13.2.2 Effect of Zinc Toxicity on Oxidative Metabolism in Plants 279 13.2.3 Effect of Zn Toxicity on Physiology and Biochemistry of Plants 280 13.3 Plants Stress Adaptation to Zinc Toxicity 281 13.4 Multi-omics Approaches for Zinc Toxicity and Tolerance in Plants 281 13.4.1 Genomics and Metabolomics 281 13.4.2 Proteomics and Transcriptomics 283 13.4.3 miRNA Omics and CRISPR/Cas9 System 284 13.4.4 Quantitative Trait Locus Mapping and Genome-Wide Association Study 286 13.5 Conclusion and Future Prospective 286 Acknowledgments 286 References 287 14 Arsenic Toxicity and Tolerance in Plants: Insights from Omics Studies 293 Barsha Majumder, Palin Sil, and Asok K. Biswas 14.1 Introduction 293 14.2 Occurrence and Distribution of As in the Environment 295 14.3 Arsenic Uptake, Accumulation, and Detoxification in Plants 296 14.3.1 Uptake of Inorganic Arsenic 296 14.3.2 Uptake of Methylated Arsenic 297 14.3.3 Arsenic Accumulation and Detoxification 297 14.3.4 Arsenic Methylation and Volatilization 298 14.4 Influence of Arsenic on Phytotoxicity 298 14.4.1 Germination and Growth 298 14.4.2 Nutrient Uptake 299 14.4.3 Oxidative Stress and Antioxidative Defense 299 14.4.4 Ascorbate–Glutathione Cycle 300 14.4.5 Photosynthesis 300 14.4.6 Respiration 301 14.4.7 Carbohydrate Metabolism 302 14.4.8 Nitrogen Metabolism 302 14.5 Modulation in “Omics” Profiling Under As Challenged Environment 303 14.5.1 Genomic Profiling 303 14.5.2 Transcriptomic Profiling 304 14.5.3 Proteomic Profiling 307 14.5.4 Metabolomic Profiling 308 14.6 Progress in Molecular Biotechnology to Evolve As-Tolerant Plants 308 14.7 Conclusion and Future Perspective 311 Acknowledgment 311 Author Contributions 312 References 312 15 Selenium Toxicity and Tolerance in Plants: Insights from Omics Studies 323 Ali Kıyak, Selman Uluısık, Ertugrul Filiz, and Firat Kurt 15.1 Introduction 323 15.2 Selenium Toxicity in Plants 324 15.2.1 Se-Induced Protein Malformation 324 15.2.2 ROS-Induced Se Phytotoxicity 325 15.3 Selenium Tolerance in Plants 326 15.4 Selenium Biofortification in Plants 328 15.5 Conclusion 329 References 330 16 Breeding for Rice Cultivars with Low Cadmium Accumulation 335 li Tang, Yaokui li, Yan Peng, Bigang Mao, Ye Shao, Zhongying Ji, and Bingran Zhao 16.1 Introduction 335 16.2 Molecular Mechanisms of Cd Accumulation in Rice 335 16.2.1 Cd Uptake 336 16.2.2 Radial Transport and Xylem Loading 338 16.2.3 Distribution of Cd in Shoots 338 16.3 Transgenic Approach for Breeding Low-Cd Rice 339 16.3.1 Traditional Transgenic Technology 339 16.3.2 Genome-Editing Technology 340 16.4 Mutation Breeding for Low-Cd Rice Cultivars 341 16.5 Molecular Marker-Assisted Breeding for Low-Cd Rice Cultivars 342 16.6 Future Perspectives 343 References 344 17 Mercury Toxicity: Plant Response and Tolerance 349 Arifin Sandhi, Abu Bakar Siddique, and Meththika Vithanage 17.1 Introduction 349 17.2 Global Mercury Pollution 350 17.3 Mercury Uptake and Toxicity in Plants 352 17.4 Existence of Differential Plant Response to Hg Stress 353 17.4.1 Plant Morphological Responses 353 17.4.2 Plant Anatomical Responses 354 17.4.3 Cellular Responses 354 17.4.4 Plant Photosynthetic Response 355 17.4.5 Enzymatic and Metabolic Responses 355 17.4.6 Plant Hormonal Responses 356 17.4.7 Reactive Oxygen Species and Oxidative Responses 356 17.5 Plant Tolerance Mechanisms 357 17.5.1 Chelation 357 17.5.2 Enzymatic and Antioxidative Tolerance 358 17.5.3 Hormonal Regulations 359 17.5.4 miRNA-Mediated Tolerance 360 17.6 Phytoremediation Prospects 360 17.7 Conclusion 361 References 362 18 Lead Toxicity and Tolerance in Plants: Insights from Omics Studies 373 Sayyeda Hira Hassan, Yassine Chafik, Manhattan Lebrun, Gabriella Sferra, Sylvain Bourgerie, Gabriella Stefania Scippa, Domenico Morabito, and Dalila Trupiano 18.1 Introduction 373 18.2 Omics’ Contribution in Uncovering Molecular Alterations in Plants Under Pb Exposure 375 18.3 Genetics and Epigenetics Regulations of Pb Toxicity and Tolerance 380 18.4 The Role of Plant Cell Wall, Cell Signaling, and Transduction 382 18.5 Pb-Binding Proteins/Transporters and Their Involvement in Tolerance 384 18.6 Pb-Induced Oxidative Stress and Antioxidative Mechanisms 385 18.7 Metabolic Pathways Associated with Pb Tolerance 388 18.7.1 Sugar/Carbohydrate and Energy Metabolic Pathway 388 18.7.2 Phenylpropanoid Pathway 389 18.7.3 Sulfur-Related Pathway and Phytohormones 390 18.8 Conclusion and Future Perspective 392 References 394 19 Interaction of Heavy Metal with Drought/Salinity Stress in Plants 407 Ziqian Li, Wentao Chen, Qianlong Tan, Yuanyuan Hou, Taimoor Hassan Farooq, Baber Iqbal, and Yong li 19.1 Introduction 407 19.2 Plant Physiology and Biochemistry 409 19.2.1 Zinc (Zn) 409 19.2.2 Cadmium (Cd) 410 19.2.3 Aluminium (Al) 411 19.2.4 Other Metals 412 19.3 Photosynthesis 413 19.4 Antioxidant System 414 19.5 Conclusions and Prospects 415 Acknowledgments 416 References 416 20 Hormonal Regulation of Heavy Metal Toxicity and Tolerance in Crop Plants 425 Éderson Akio Kido, Gizele de Andrade Luz, Valquíria da Silva, Maria Fernanda da Costa Gomes, and José Ribamar Costa Ferreira Neto 20.1 Introduction 425 20.2 General Aspects of Plants Under HM Stress 426 20.3 Phytohormone-Mediating Plant Response to HM Stress 427 20.3.1 Abscisic Acid 430 20.3.2 Auxin 432 20.3.3 Brassinosteroid 434 20.3.4 Cytokinin 435 20.3.5 Ethylene 437 20.3.6 Gibberellin 438 20.3.7 Jasmonate 439 20.3.8 Melatonin (MT) 440 20.3.9 Salicylic Acid (SA) 442 20.3.10 Strigolactone (SL) 444 20.4 Crosstalk of Phytohormones in Plants Responding to Heavy Metals 445 20.5 Final Considerations 447 References 448 21 Heavy-Metal-Induced Reactive Oxygen Species and Methylglyoxal Formation and Detoxification in Crop Plants: Modulation of Tolerance by Exogenous Chemical Compounds 461 Beatrycze Nowicka, Tahsina Sharmin Hoque, Sheikh Mahfuja Khatun, Jannatul Naim, Ahmed Khairul Hasan, and Mohammad Anwar Hossain 21.1 Introduction 461 21.2 Heavy-Metal-Induced ROS and Methylglyoxal Production in Plant Cells 464 21.3 Detoxification of ROS and Methylglyoxal in Plant Cells 468 21.4 Exogenous Chemical-Compounds-Mediated Heavy Metal/Metalloid Tolerance in Crop Plants 473 21.5 Conclusions and Future Perspectives 484 References 486 22 Biochar Amendments in Soils and Heavy Metal Tolerance in Crop Plants 493 Agnieszka Medyńska-Juraszek and Bhakti Jadhav 22.1 Introduction 493 22.2 Heavy Metal Immobilization Mechanisms on Biochar 495 22.2.1 Heavy Metal Immobilization Through Soil pH Modification 496 22.3 Biochar Interactions Through Rhizosphere 496 22.3.1 Effect on Plant Root Development 497 22.3.2 Changes in Elements Uptake from Rhizosphere 498 22.4 Biochar-Induced Plant Respond to Metal Stress 499 22.4.1 Biochar Induces Changes in Photosynthetic Activity 499 22.4.2 Biochar Induces Changes in Antioxidant and Phytohormone Activity 499 22.4.3 Biochar as a Source of Specific Chemical Compounds Affecting Heavy Metal Uptake By Plants 501 22.5 Effect of Biochar on Heavy Metal Concentrations in Different Crops 503 22.6 Effect of Biochar Type on Heavy Metal Immobilization 503 References 504 23 Plant-Growth-Promoting Rhizobacteria and Their Metabolites: Clean and Green Approaches to Deal with Heavy Metal Toxicity 513 Imtinen Sghaier, Ameur Cherif, and Mohamed Neifar 23.1 Introduction 513 23.2 Chemical Fertilizers and Their Impacts 515 23.2.1 Impacts of Chemical Fertilizers on Atmospheric Ecosystem 515 23.2.2 Impacts of Chemical Fertilizers on Aquatic Ecosystem 515 23.2.3 Impacts of Chemical Fertilizers on Soil 515 23.2.4 Impacts of Chemical Fertilizers on Plants 516 23.3 PGPR and Biofertilization Traits 516 23.3.1 Acquisition of Nutrients 516 23.3.2 Production of Siderophores 517 23.3.3 Production of Exopolysaccharides 517 23.4 Resistance to Abiotic Stress 518 23.5 Biostimulation Potential and PGPR 519 23.6 Biocontrol Potential and PGPR 520 23.7 PGPR and Heavy Metal Bioremediation 521 23.8 Conclusion and Future Prospects 524 Acknowledgments 525 References 525 24 Applications of Nanotechnology for Improving Heavy Metal Stress Tolerance in Crop Plants 533 Meng Jiang, Yue Song, Mukesh Kumar Kanwar, and Jie Zhou 24.1 Introduction 533 24.2 Impacts of NPs on the HM Stress in Plants 535 24.2.1 Silicon 535 24.2.2 Selenium 535 24.2.3 Iron 536 24.2.4 Zinc Oxide 537 24.2.5 Titanium Dioxide 537 24.2.6 Cerium Dioxide 538 24.3 Mechanisms of NPs to Mitigate the Toxicity of HM 539 24.4 Summary and Prospect 543 References 545 25 The Dynamics of Phytoremediation of Heavy Metals: Recent Progress and Future Perspective 553 Imran Haider Shamsi, Xiaoli Jin, Xin Zhang, Qidong Feng, Zakir Ibrahim, Muhammad Faheem Adil, Muhammad Fazal Karim, and Najeeb Ullah 25.1 Introduction 553 25.1.1 Types of Phytoremediation 554 25.1.1.1 Phytostabilization 554 25.1.1.2 Phytovolatalization 554 25.1.1.3 Phytoextraction 554 25.1.2 Modified Concept 555 25.1.2.1 Chemical-Assisted Phytoremediation Employing Non-hyperaccumulator Plants 556 25.1.2.2 Biochar-Assisted Phytoremediation 556 25.1.2.3 Microbial-Assisted Phytoremediation 557 25.2 Importance of Phytoremediation 557 25.3 Role of Phytoremediation as a Sustainable Solution 558 25.4 Biophilic Design as Phytoremediation in Urban Sustainability 559 25.4.1 Eco-Design 559 25.4.2 Biophilic Design 559 25.4.2.1 Hypothesis of Biophilic 562 25.4.2.2 Dimensions of Biophilic Design 562 25.4.2.3 Direct Experience of Nature 562 25.4.2.4 Indirect Experience of Nature 563 25.4.2.5 Experience of Place and Space 563 25.4.2.6 Sustainable Biophilic Cities 563 25.4.3 Health Benefits 564 25.4.4 Biophilic as an Antidepressant in Urban Environment 565 25.4.5 Economic Benefits 566 25.4.6 Sustainability and Resilience 566 25.5 Conclusion 567 25.6 Future Perspective 568 Acknowledgment 569 References 569 26 Genetic Engineering for Heavy Metal/Metalloid Stress Tolerance in Plants 573 Mohammad Anwar Hossain, Md. Tahjib-Ul-Arif , Sopnil Ahmed Jahin, Abu Bakar Siddique, Mumtarin Haque Mim, Sharif-Ar-Raffi, Muhammad Javidul Haque Bhuiyan, and Beatrycze Nowicka 26.1 Introduction 573 26.2 Mechanisms of Heavy Metal/Metalloid Tolerance in Plants 574 26.3 Strategies for Improving Metal/Metalloid Stress Tolerance in Plants 576 26.4 Transgenic Plants and Heavy Metal/Metalloid Stress Tolerance in Plants 577 26.4.1 Sulfur Metabolism Engineering and Heavy Metal Tolerance 577 26.4.2 Glyoxalase Pathway Genes and Heavy Metal Stress Tolerance 577 26.4.3 Enhanced Antioxidant Defense and Heavy Metal Tolerance 579 26.4.4 Phytochelatin and Metallothionein Genes and Heavy Metal Tolerance 579 26.4.5 Metal Ion Transporter Genes/Proteins and Heavy Metal Stress Tolerance 579 26.5 CRISPR/Cas System and Heavy Metal Tolerance Development 585 26.6 Conclusions and Future Prospects 585 Acknowledgment 586 References 586 Index 593

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Book SynopsisFRUIT AND VEGETABLES HARVESTING, HANDLING AND STORAGE The second edition of this very well-received book, which in its first edition was entitled Postharvest Technology of Fruits and Vegetables, has been welcomed by the community of postharvest physiologists and technologists who found the first edition of such great use. The book covers, in comprehensive detail, postharvest physiology as it applies to postharvest quality, technology relating to maturity determination, harvesting, packaging, postharvest treatments, controlled atmosphere storage, ripening and transportation on a very wide international range of fruits and vegetables. The new edition of this definitive work, which contains many full colour photographs, provides key practical and commercially-oriented information of great use in helping to ensure that fruit and vegetables reach the retailer in optimum condition, with the minimum of loss and spoilage. Fruits and vegetables, 2nd eTrade Review"The coloured photography is the best I have ever seen, The index and references are complete and extremely detailed - in fact, perfect. The author has spent his entire life in agriculture for the benefit of others. A superb book." Food & Beverage Reporter, April 2005 "It is indisputable that Fruit and Vegetables - Harvesting, Handling and Storage, second edition will be a very fitted and servicable book for those who are closely related to crop production and marketing." International Journal of Food Science and Technology, 2006Table of ContentsPreface. Acknowledgements. 1. Preharvest Factors on Postharvest Life. 2. Assessment of Crop Maturity. 3. Harvesting and Handling Methods. 4. Precooling. 5. Packaging. 6. Postharvest Treatments. 7. Storage. 8. Disease Control. 9. Safety. 10. Fruit Ripening Conditions. 11. Marketing and Transport. 12. Postharvest Technology of Fruits and Vegetables. Appendices. References. Index.

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Book SynopsisFirst published in 1989, Physiology of Crop Yield was the first student textbook to digest and assimilate the many advances in crop physiology, within a framework of resource capture and use. Retaining the central core of the first edition, this long-awaited second edition draws on recent developments in areas such as phenology, canopy dynamics and crop modelling, and the concepts of sustainable crop production. A broad perspective is developed, from the gene through the plant and crop to the ecosystem, covering: Advances in molecular biology relating to crop science Limitation of crop yield by the supply of water or nitrogen Global climate change and its impact on crop modelling Physiological aspects of crop quality A wider range of species, with emphasis on wheat, maize and soybean This book will be a valuableTrade Review"Physiology of Crop Yield would be useful to any scientist who works to integrate and better understand growth, development and yield from a perspective of whole plant physiology. This is a much needed and timely publication." P.V. Vara Prasad, Kansas State University "Hay and Porter have produced an excellent book, well-suited for undergraduate teaching and for those seeking an overview of processes contributing to crop yield. They even tell us how long the sun needs to shine to deliver a bowl of breakfast cereal." Tim Wheeler, University of Reading "Although described as the second edition of An Introduction to the Physiology of Crop Yield, which was authored by R. Hay and A. J. Walker (1989). The Physiology of Crop Yield is completely rewritten and focuses more explicitly on quantitative prediction of Crop growth. The Physiology of Crop Yield contains numerous line drawings and tables, as well as 30 pages of reference. The overall layout and design of text, tables, and figures follows that of traditional textbooks...the text seems well suited for an upper-level undergraduate course with a pre-requisite of plant physiology." Jeffrey W. White reproduced from Crop Science "This book extensively covers the theoretical aspects of crop physiological processes...It is useful for understanding and interpreting agronomic phenomena and therfore clearly has a considerable value to advanced students, teachers and scientists in the field of agronomy, crop management and even plant breeding. The array of literature cited is broad and also up-to-date. The Order of presentation is logical and comprehensive overviews are given...it remains an excellent reference that should be recommended for any teaching of crop phsiology at the graduate level." Annals of Botany, 1-2, 2007Table of ContentsPreface ix Copyright acknowledgements xi 1 Introduction 1 2 Development and phenology 7 2.1 Crop development: concepts and tools 8 2.1.1 Growth stages and phasic development 9 2.1.2 Events at the stem apex: the leek as a simple model species 11 2.1.3 Events at stem apices: branching and reproductive development in wheat 13 2.1.4 Events at stem apices: the consequences of separation of male and female organs in maize 15 2.1.5 Phenology determined by events at axillary meristems: determinate and indeterminate soybean varieties 18 2.1.6 Components of yield 21 2.2 Case histories: the influence of environment and management on crop development and phenology 22 2.2.1 Convergence and synchrony: the influence of sowing date on winter wheat in Northern Europe 22 2.2.2 Crop improvement and the anthesis–silking interval in maize 25 2.2.3 Adaptation of soybean to different latitudes: phasic analysis of the photoperiodic control of flowering 26 2.2.4 Development in storage: physiological age and tuber initiation in the potato 30 2.2.5 Complementary phenologies and plant habits in mixed cropping: temperate grass/clover swards 32 3 Interception of solar radiation by the canopy 35 3.1 The life history of a leaf 35 3.2 The components of plant leaf area expansion 40 3.2.1 Crop emergence 40 3.2.2 Leaf production 41 3.2.3 Leaf expansion 43 3.2.4 Branching 47 3.2.5 Senescence, removal and damage – leaf lifespan 50 3.3 The development of the crop canopy: leaf area index 53 3.3.1 Seasonal development of leaf area index 53 3.3.2 Leaf area index and crop management 55 3.4 Canopy architecture and the interception of solar radiation 60 3.4.1 Seasonal patterns of interception 60 3.4.2 Optimum and critical leaf area indices 61 3.4.3 Leaf photosynthesis and canopy properties 63 3.4.4 Canopy extinction coefficient 66 4 Photosynthesis and photorespiration 73 4.1 Introduction 73 4.2 Photosynthetic efficiency 75 4.3 Photosynthetic processes 80 4.3.1 Photosynthesis as a cellular biochemical process 80 4.3.2 Photosynthesis as a leaf diffusive process 89 4.3.3 Photosynthesis as a crop canopy process 95 4.4 The C 4 photosynthesis mechanism 99 4.5 Water shortage and photosynthesis 104 4.6 Nitrogen effects on photosynthesis 109 4.7 Ozone effects on photosynthesis and crop productivity 112 5 The loss of CO 2 : respiration 117 5.1 Introduction 117 5.2 The basis of crop respiration 120 5.3 Growth and maintenance respiration 123 5.4 The respiration of different plant substrates 126 5.5 Growth and maintenance respiration in the field 130 5.6 Respiration associated with crop processes 134 5.7 Environmental effects on respiration 140 5.8 Crop respiration in the future 142 6 The partitioning of dry matter to harvested organs 145 6.1 The processes and pathways of assimilate partitioning 145 6.2 Ontogeny and assimilate partitioning: a survey of source/sink relationships 148 6.3 Time courses of dry matter partitioning: harvest index 151 6.4 Limitation of yield by source or sink 153 6.5 Sink limitation of yield in cereals – physiology of ineffective grain setting 157 6.6 Assimilate partitioning and crop improvement: historic trends in harvest index of wheat and barley 162 6.7 Assimilate partitioning and crop improvement: historic trends in harvest index of maize 165 6.8 Assimilate partitioning to potato tubers 167 6.9 Assimilate partitioning in grassland: implications for management of grass yield 171 6.10 Assimilate partitioning in grassland: implications for the overwintering and early growth of white clover 176 6. 11 Assimilate partitioning in diseased plants: temperate cereals affected by biotrophic fungal pathogens 178 7 Limiting factors and the achievement of high yield 180 7.1 Limitation by water supply 181 7.1.1 Acquisition of water 182 7.1.2 Water use efficiency 186 7.1.3 Crop yield where water supply is limiting 190 7.2 Limitation by nitrogen supply 193 7.2.1 Acquisition of nitrogen 193 7.2.2 Nitrogen use efficiency 196 7.2.3 Crop yield where N supply is limiting 200 7.3 Achieving high yield: resource capture and assimilate partitioning 202 8 Physiology of crop quality 205 8.1 Wheat: protein content 206 8.2 Soybean: oil and protein contents 209 8.3 Oilseed rape: glucosinolates and erucic acid 212 8.4 Potato: tuber size and processing quality 215 8.5 The quality of conserved forages: ontogeny and yield 217 9 The simulation modelling of crops 222 9.1 Introduction 222 9.2 Building a crop model 225 9.3 Crop models of wheat (AFRC2), soybean (CROPGRO) and maize 227 9.3.1 The AFRC2 wheat model 228 9.3.2 The CROPGRO soybean model 243 9.3.3 The maize model 253 9.4 Modelling variety differences and traits 257 9.5 Conclusions 261 10 Crop physiology: the future 264 10.1 Introduction 264 10.2 Lowering inputs 265 10.3 Climate change 267 10.4 Quality 269 10.5 New crops 270 10.6 The potential for increasing crop photosynthesis and yield 272 10.7 The last words 275 References 277 Index 309

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Book SynopsisPlant diseases worldwide are responsible for billions of dollars worth of crop losses every year. With less agrochemicals being used and less new fungicides coming on the market due to environmental concerns, more effort is now being put into the use of genetic potential of plants for pathogen resistance and the development of induced or acquired resistance as an environmentally safe means of disease control. This comprehensive book examines in depth the development and exploitation of induced resistance. Chapters review current knowledge of the agents that can elicit induced resistance, genomics, signalling cascades, mechanisms of defence to pests and pathogens and molecular tools. Further chapters consider the topical application of inducers for disease control, microbial induction of pathogen resistance, transgenic approaches, pathogen population biology, trade offs associated with induced resistance and integration of induced resistance in crop protection. The book concludTrade Review"It is certainly a book for libraries in universities and institues active in biological and agricultural research. This book will also interest individual scientists who are specifically working on induced resistance because of its extensive references" Plant Pathology, 2007 'The book is essential reading for those undertaking research related to the subject and of relevance to all involved in crop protection R & D' Experimental Agriculture, 2008Table of ContentsList of contributors. Preface. Chapter 1: Introduction: definitions and some history. Ray Hammerschmidt. Chapter 2: Agents that can elicit induced resistance. Gary D Lyon. Chapter 3: Genomics in induced resistance. Kemal Kazan and Peer Schenk. Chapter 4: Signalling cascades involved in induced resistance. Corne MJ Pieterse and LC Van Loon. Chapter 5: Types and mechanisms of rapidly-induced plant resistance to herbivorous arthropods. Michael J Stout. Chapter 6: Mechanisms of defence to pathogens: biochemistry and physiology. Christophe Garcion, Olivier Lamotte and Jean-Pierre Metraux. Chapter 7: Induced resistance in natural ecosystems and pathogen population biology: exploiting interactions. Adrian Newton and Joern Pons. Chapter 8: Microbial induction of resistance to pathogens. Dale Walters and Tim Daniell. Chapter 9: Trade-offs associated with induced resistance. Martin Heil. Chapter 10: Topical induction of inducers for disease control. Philippe Reignault and Dale Walters. Chapter 11: Integration of induced resistance in crop production. Tony Reglinski, Elizabeth Dann and Brian Deverall. Chapter 12: Exploitation of induced resistance: a commercial perspective. Andy Leadbeater and Theo Staub. Chapter 13: Induced resistance in crop protection: the future, drivers and. barriers. Gary Lyon, Adrian Newton and Dale Walters. Index

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Book SynopsisThe first book to tell the shocking story of Golden Rice, a genetically modified grain that provides essential Vitamin A and can save lives in developing countriesif only they were allowed to grow it. Ordinary white rice is nutrient poor; it consists of carbohydrates and little else. About one million people who subsist on rice become blind or die each year from vitamin A deficiency. Golden Rice, which was developed in the hopes of combatting that problem by a team of European scientists in the late '90s, was genetically modified to provide an essential nutrient that white rice lacks: beta-carotene, which is converted into vitamin A in the body. But twenty years later, this potentially sight- and life-saving miracle food still has not reached the populations most in needand tens of millions of people in India, China, Bangladesh, and throughout South and Southeast Asia have gone blind or have died waiting. Supporters claim that the twenty-year delay in Golden Rice's introduction is anTrade ReviewGolden Rice is a thoughtful and carefully documented tale of how difficult it can be to take something that works in the laboratory and get it to the people who stand to benefit from it.—Andrew J. Wight, ScienceIn just over 200 pages, Regis gives a crash course on genetic engineering and explains the messy history of Golden Rice, disabusing the reader of many popular myths along the way.—The Genetic Literacy ProjectTable of ContentsPrefaceChapter 1. Child Killer Chapter 2. Proof of ConceptChapter 3. GR 0.5 and BeyondChapter 4. The ProtocolChapter 5. What Is a GMO?Chapter 6. Safe to Eat?Chapter 7. Golden Rice 2Chapter 8. Better Than SpinachChapter 9. The MistakeChapter 10. The "Crime against Humanity"Chapter 11. The ApprovalsEpilogue. The Proactionary PrincipleAcknowledgmentsAppendix. L'affaire SchubertBibliographyIndex

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Book SynopsisThe potato has a larger story to tell than its humble status suggests. In this account of the potato and its role in human history - and the human future - James Lang tells that story. Combining biology and social science, he describes the origins of cultivated potatoes; the many ways to propagate, store, and harvest potatoes; and the crop's potential for feeding a hungry planet. Along the way, Lang also muses on art and agriculture, reflects on famine and demography, describes villagebased farmer field schools, and looks at the role the potato plays in China and other key areas of the world. Native to the New World, the potato was first domesticated by Andean farmers, probably in the Lake Titicaca basin. Full of essential vitamins and energy-giving starch, the potato has proved a valuable world resource. Curious Spaniards took the potato back to Europe, from whence it spread worldwide. Today, the largest potato producer is China, with India not far behind. From the many potato projects he studied, Lang learned a simple, direct lesson: how to address basic problems with practical solutions. Whether the problem is seed production, pest management, genetic improvement, or storage, effective projects must take the diversity imposed by place and by farming traditions as a starting point. In agriculture, one size does not fit all. Notes of a Potato Watcher is a book that anyone interested in food crops and small farms will not want to miss, a book that explains why the potato was not the culprit in the Irish famine, and a book that shows why solutions must begin at home.

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Book SynopsisThe potato has a larger story to tell than its humble status suggests. In this account of the potato and its role in human history - and the human future - James Lang tells that story. Combining biology and social science, he describes the origins of cultivated potatoes; the many ways to propagate, store, and harvest potatoes; and the crop's potential for feeding a hungry planet. Along the way, Lang also muses on art and agriculture, reflects on famine and demography, describes villagebased farmer field schools, and looks at the role the potato plays in China and other key areas of the world. Native to the New World, the potato was first domesticated by Andean farmers, probably in the Lake Titicaca basin. Full of essential vitamins and energy-giving starch, the potato has proved a valuable world resource. Curious Spaniards took the potato back to Europe, from whence it spread worldwide. Today, the largest potato producer is China, with India not far behind. From the many potato projects he studied, Lang learned a simple, direct lesson: how to address basic problems with practical solutions. Whether the problem is seed production, pest management, genetic improvement, or storage, effective projects must take the diversity imposed by place and by farming traditions as a starting point. In agriculture, one size does not fit all. Notes of a Potato Watcher is a book that anyone interested in food crops and small farms will not want to miss, a book that explains why the potato was not the culprit in the Irish famine, and a book that shows why solutions must begin at home.

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Book SynopsisShould you buy organic food? Is it just a status symbol, or is it really better for us? Is it really better for the environment? What about organic produce grown thousands of miles from our kitchens, or on massive corporately owned farms? Is “local” or “small-scale” better, even if it’s not organic? A lot of consumers who would like to do the right thing for their health and the environment are asking such questions.Sapna Thottathil calls on us to rethink the politics of organic food by focusing on what it means for the people who grow and sell it—what it means for their health, the health of their environment, and also their economic and political well-being. Taking readers to the state of Kerala in southern India, she shows us a place where the so-called “Green Revolution” program of hybrid seeds, synthetic fertilizers, and rising pesticide use had failed to reduce hunger while it caused a cascade of economic, medical, and environmental problems. Farmers burdened with huge debts from buying the new seeds and chemicals were committing suicide in troubling numbers. Farm labourers suffered from pesticide poisoning and rising rates of birth defects. A sharp fall in biodiversity worried environmental activists, and everyone was anxious about declining yields of key export crops like black pepper and coffee.In their debates about how to solve these problems, farmers, environmentalists, and policymakers drew on Kerala’s history of and continuing commitment to grassroots democracy. In 2010, they took the unprecedented step of enacting a policy that requires all Kerala growers to farm organically by 2020. How this policy came to be and its immediate economic, political, and physical effects on the state’s residents offer lessons for everyone interested in agriculture, the environment, and what to eat for dinner. Kerala’s example shows that when done right, this kind of agriculture can be good for everyone in our global food system.

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Book SynopsisIn recent decades, there has been an increase in the demand for food production. This is attributed to the growth of the human population and the development of new farming techniques. Innovative management solutions are required to make the most out of agricultural inputs while simultaneously reducing their off-site mobility and the impacts they have on the ecosystems. The primary contributors to the contamination of local soils, sediments, and streams are activities that are associated with horticulture, agriculture, and industrial output. Examples of agricultural pollutants include organic wastes such as manure and decaying plants; runoff from irrigation systems including salts and trace metals; microorganisms; pesticides, herbicides, and insecticides; and chemical herbicides, pesticides, and insecticides. Utilizing pollution management measures that are both effective and cost-effective is one way to produce more productive agricultural outputs. Applications of fertilizer that are targeted, appropriate, and well-balanced are important if one want to increase agricultural output while at the same time limiting their influence on the environment. To advance global crop production in a way that is both efficient and kind to the environment, every effort should be made to improve the availability and utilization of secondary and micronutrients, organic fertilizers, and techniques for soil conservation. This should be done without compromising the soil's overall health or its level of productivity. Taking this action is required to increase the crop yields. As a result of this, it is of the utmost importance to find solutions to the challenging issues that crop up on a regular basis in the agricultural industry. As a direct result of the data presented up top, we are thinking of writing a book with the working title Contaminants in Agriculture: Sources, Impacts, and Management. This book focuses on the many different outcomes that could be brought about by the existing scenario. It is our steadfast opinion that this volume will prove to be a resource that is important for anybody who is interested in agriculture or who is curious about agriculture.Table of Contents Chapter 1 The Largest Source of Agricultural Pollution Chapter 2 Contaminants and Their Effect on Agricultural Crops Chapter 3 Impacts of Agricultural Contaminants on Both People and Animals Chapter 4 Crop Contaminant Types, Detection, Monitoring Chapter 5 How Industrial Agriculture Affects Our Water Chapter 6 Agricultural Policy to Contamination Chapter 7 Measures For Protecting Agricultural Soils from Contamination Chapter 8 Challenges to the Prevention of Agricultural Pollution Chapter 9 The Future of Agricultural Contaminant Management Chapter 10 Universal Bodies Pushing For Sustainable Contaminant-Free Agriculture

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Book SynopsisBioactive plant molecules have been found to have a variety of biological actions that can benefit human health and well-being over the years. Phytochemicals, commonly referred to as bioactive plant molecules, are naturally occurring substances that are found in plants and have been shown to offer potential health advantages. Bioactive Molecules In Plant Foods: An Explorative is a comprehensive book that gives information about Bioactive molecules, their health benefits, seed storage protein, and the chemistry and bioactivity of different compounds. This book also highlights its various application in various medicinal fields. Additionally, this book also describes different extraction techniques. Readers from a variety of backgrounds, such as researchers, teachers, students, and biological scientists, will find this book to be equally helpful.Table of Contents Chapter 1 Introduction To Bioactive Molecules Chapter 2 Health Benefits of Dietary Bioactive Molecules in Plants Chapter 3 Seed Storage Proteins As Sources of Bioactive Peptides Chapter 4 Chemistry And Bioactivity of Food Phytoalexin Chapter 5 Bioactivity of Flaxseed Lignans Chapter 6 Bioactivity of Alkylresorcinols Chapter 7 Optimal Utilization of Bioactive Molecules in the Medical Field Chapter 8 Bioactive Lipids Chapter 9 Potential Applications of Bioactive Molecules Chapter 10 Technologies for Extraction of Plant Bioactive Compounds

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Book SynopsisTo adequately feed the world by the year 2050, FAO (Food and Agriculture organization) estimates that food production must increase by 50 – 66 percent in developed and developing countries consecutively. However, current yield trends show that stagnation or the opposite is happening. Under current farming management regimes, it seems almost impossible to achieve this aim of doubling production. Thus, the front of constant genetic advancement of current agricultural crop and animals are suggested. This book explains the concepts and misconceptions of genetically modified organisms and their potential and threat to sustainable agriculture. The reader is provided with a detailed description of GMO procedures and machines involved. The books also take the readers through the changing definition around GMOs, the organization and policy involved in deferent political regions. By taking the reader through some of the most successful GMOs, the book can help farmers choose the best GMO innovations without fear of negative health and environmental effects.Table of Contents Chapter 1 Introduction to GMOs Chapter 2 Non-Genetic Engineering Methods and Mechanisms Chapter 3 Genetic Engineering Techniques Chapter 4 Genetic Engineering In Animals Chapter 5 Genetically Modified Crops Chapter 6 Genetically Modified Animals

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