Sie sind bereits eingeloggt. Klicken Sie auf 2. tolino select Abo, um fortzufahren.
Bitte loggen Sie sich zunächst in Ihr Kundenkonto ein oder registrieren Sie sich bei bücher.de, um das eBook-Abo tolino select nutzen zu können.
This book focuses on the conventional breeding approach, and on the latest high-throughput genomics tools and genetic engineering / biotechnological interventions used to improve rice quality. It is the first book to exclusively focus on rice as a major food crop and the application of genomics and genetic engineering approaches to achieve enhanced rice quality in terms of tolerance to various abiotic stresses, resistance to biotic stresses, herbicide resistance, nutritional value, photosynthetic performance, nitrogen use efficiency, and grain yield. The range of topics is quite broad and…mehr
This book focuses on the conventional breeding approach, and on the latest high-throughput genomics tools and genetic engineering / biotechnological interventions used to improve rice quality. It is the first book to exclusively focus on rice as a major food crop and the application of genomics and genetic engineering approaches to achieve enhanced rice quality in terms of tolerance to various abiotic stresses, resistance to biotic stresses, herbicide resistance, nutritional value, photosynthetic performance, nitrogen use efficiency, and grain yield. The range of topics is quite broad and exhaustive, making the book an essential reference guide for researchers and scientists around the globe who are working in the field of rice genomics and biotechnology. In addition, it provides a road map for rice quality improvement that plant breeders and agriculturists can actively consult to achieve better crop production.
Aryadeep Roychoudhury is working as Assistant Professor at the Department of Biotechnology, St. Xavier’s College (Autonomous), Kolkata, West Bengal, India. He received his B.Sc. (Hons.) in Botany from Presidency College, Kolkata, and M.Sc. in Biophysics and Molecular Biology, University of Calcutta, West Bengal, India. He did his Ph.D. from Bose Institute, Kolkata, under Jadavpur University, Kolkata. His Ph.D. thesis was mostly based on characterization of different salt-inducible genes in rice. Following his Ph.D. work, he joined as Research Associate (Postdoctorate) at the University of Calcutta, continuing with rice as model system. Dr. Roychoudhury is currently handling several government-funded projects on abiotic stress responses in rice and supervising five (05) Ph.D. students as Principal Investigator. To date, he has published over 110 articles in peer-reviewed journals and chapters in books of international and national repute. He is a regular reviewer of articles in high-impact, international journals, life member of different scientific associations and societies, and the recipient of the Young Scientist Award 2019, conferred upon him by International Foundation for Environment and Ecology, at the University of Allahabad, Prayagraj, Uttar Pradesh.
Inhaltsangabe
Chapter 1. Understanding the mechanism of host-pathogen interaction in rice through genomics approaches.- Chapter 2. Genetic engineering and Genome editing strategies to enhance resistance of rice plants to diseases: a review of progress and future prospects.- Chapter 3: Transgenic rice live against bacterial blight.- Chapter 4. Genetic Engineering of Cultivated Rice for Viral Resistance.- Chapter 5. Genomics and genetic engineering for polyamine-mediated tolerance of rice against pathogen infection.- Chapter 6. Genomics and genetic engineering of rice for resistance to different insect pests.- Chapter 7. Genetic engineering of rice for resistance to insect pests.- Chapter 8. Increasing rice grain yield under biotic stresses: mutagenesis.- Chapter 9. Temporal and spatial dynamics of microbial communities in a genetically modified rice ecosystem.- Chapter 10. Genetic Engineering for Developing Herbicide Resistance in Rice Crops.- Chapter 11. An insight into the factors regulating flowering in rice: From genetics to epigenetics.- Chapter 12. Breeding and Bioengineering of male sterility in rice.- Chapter 13. Male sterility system for hybrid rice breeding and seed production.- Chapter 14. Advancement in tracking down nitrogen use efficiency in rice: Molecular breeding and genomics insight.- Chapter 15. Improving Water use Efficiency and Nitrogen use Efficiency in Rice through Breeding and Genomics Approaches.- Chapter 16. Rice breeding and genomics approaches for improving water and nitrogen use efficiency.- Chapter 17. Aromatic rice: biochemical and molecular basis of aroma production and stress response.- Chapter 18. Genomics and genetic engineering of rice elucidating cross-talk between stress signaling and nutrition enhancement via regulation of antioxidant, osmolyte and metabolite levels.- Chapter 19. Genetically modified rice stacked with antioxidants for nutrient enhancement and stress tolerance.- Chapter 20. Breeding and QTL mapping for γ-oryzanol and nutrition content in rice.- Chapter 21. Genetic Enhancement of Nutritional Traits in Rice Grains through Marker Assisted Selection and Quantitative Trait Loci.- Chapter 22. Breeding approaches to generate biofortified rice for nutritional enhancement.-Chapter 23. Ameliorating nutritional, protein and vitamin content on rice seed through classic mating and advanced genetic technology.- Chapter 24: Genetic engineering of rice to fortify micronutrients.- Chapter 25. Golden Rice: genetic engineering, promises, present status and future prospects.- Chapter 26. Biofortification of rice with iron and zinc: progress and prospects.- Chapter 27. Biofortification of iron, zinc and selenium in rice for better quality.- Chapter 28. Micronutrient biofortification in rice for better quality.- Chapter 29. Rice Genetic Engineering for Increased Amino Acid and Vitamin Contents.- Chapter 30. Biofortification of iron, selenium and zinc in rice for quality improvement.- Chapter 31. Quantitative trait loci for rice grain quality improvement.- Chapter 32. Improvement of rice quality via biofortification of selenium, iron and zinc and its starring role in human health.- Chapter 33. Improvement of rice quality via biofortification of micronutrients.- Chapter 34. Involvement of policy makers, public acceptance and commercialization of nutritionally enhanced and genetically modified rice.-
Chapter 1. Understanding the mechanism of host-pathogen interaction in rice through genomics approaches.- Chapter 2. Genetic engineering and Genome editing strategies to enhance resistance of rice plants to diseases: a review of progress and future prospects.- Chapter 3: Transgenic rice live against bacterial blight.- Chapter 4. Genetic Engineering of Cultivated Rice for Viral Resistance.- Chapter 5. Genomics and genetic engineering for polyamine-mediated tolerance of rice against pathogen infection.- Chapter 6. Genomics and genetic engineering of rice for resistance to different insect pests.- Chapter 7. Genetic engineering of rice for resistance to insect pests.- Chapter 8. Increasing rice grain yield under biotic stresses: mutagenesis.- Chapter 9. Temporal and spatial dynamics of microbial communities in a genetically modified rice ecosystem.- Chapter 10. Genetic Engineering for Developing Herbicide Resistance in Rice Crops.- Chapter 11. An insight into the factors regulating flowering in rice: From genetics to epigenetics.- Chapter 12. Breeding and Bioengineering of male sterility in rice.- Chapter 13. Male sterility system for hybrid rice breeding and seed production.- Chapter 14. Advancement in tracking down nitrogen use efficiency in rice: Molecular breeding and genomics insight.- Chapter 15. Improving Water use Efficiency and Nitrogen use Efficiency in Rice through Breeding and Genomics Approaches.- Chapter 16. Rice breeding and genomics approaches for improving water and nitrogen use efficiency.- Chapter 17. Aromatic rice: biochemical and molecular basis of aroma production and stress response.- Chapter 18. Genomics and genetic engineering of rice elucidating cross-talk between stress signaling and nutrition enhancement via regulation of antioxidant, osmolyte and metabolite levels.- Chapter 19. Genetically modified rice stacked with antioxidants for nutrient enhancement and stress tolerance.- Chapter 20. Breeding and QTL mapping for Gamma-oryzanol and nutrition content in rice.- Chapter 21. Genetic Enhancement of Nutritional Traits in Rice Grains through Marker Assisted Selection and Quantitative Trait Loci.- Chapter 22. Breeding approaches to generate biofortified rice for nutritional enhancement.-Chapter 23. Ameliorating nutritional, protein and vitamin content on rice seed through classic mating and advanced genetic technology.- Chapter 24: Genetic engineering of rice to fortify micronutrients.- Chapter 25. Golden Rice: genetic engineering, promises, present status and future prospects.- Chapter 26. Biofortification of rice with iron and zinc: progress and prospects.- Chapter 27. Biofortification of iron, zinc and selenium in rice for better quality.- Chapter 28. Micronutrient biofortification in rice for better quality.- Chapter 29. Rice Genetic Engineering for Increased Amino Acid and Vitamin Contents.- Chapter 30. Biofortification of iron, selenium and zinc in rice for quality improvement.- Chapter 31. Quantitative trait loci for rice grain quality improvement.- Chapter 32. Improvement of rice quality via biofortification of selenium, iron and zinc and its starring role in human health.- Chapter 33. Improvement of rice quality via biofortification of micronutrients.- Chapter 34. Involvement of policy makers, public acceptance and commercialization of nutritionally enhanced and genetically modified rice.-
Chapter 1. Understanding the mechanism of host-pathogen interaction in rice through genomics approaches.- Chapter 2. Genetic engineering and Genome editing strategies to enhance resistance of rice plants to diseases: a review of progress and future prospects.- Chapter 3: Transgenic rice live against bacterial blight.- Chapter 4. Genetic Engineering of Cultivated Rice for Viral Resistance.- Chapter 5. Genomics and genetic engineering for polyamine-mediated tolerance of rice against pathogen infection.- Chapter 6. Genomics and genetic engineering of rice for resistance to different insect pests.- Chapter 7. Genetic engineering of rice for resistance to insect pests.- Chapter 8. Increasing rice grain yield under biotic stresses: mutagenesis.- Chapter 9. Temporal and spatial dynamics of microbial communities in a genetically modified rice ecosystem.- Chapter 10. Genetic Engineering for Developing Herbicide Resistance in Rice Crops.- Chapter 11. An insight into the factors regulating flowering in rice: From genetics to epigenetics.- Chapter 12. Breeding and Bioengineering of male sterility in rice.- Chapter 13. Male sterility system for hybrid rice breeding and seed production.- Chapter 14. Advancement in tracking down nitrogen use efficiency in rice: Molecular breeding and genomics insight.- Chapter 15. Improving Water use Efficiency and Nitrogen use Efficiency in Rice through Breeding and Genomics Approaches.- Chapter 16. Rice breeding and genomics approaches for improving water and nitrogen use efficiency.- Chapter 17. Aromatic rice: biochemical and molecular basis of aroma production and stress response.- Chapter 18. Genomics and genetic engineering of rice elucidating cross-talk between stress signaling and nutrition enhancement via regulation of antioxidant, osmolyte and metabolite levels.- Chapter 19. Genetically modified rice stacked with antioxidants for nutrient enhancement and stress tolerance.- Chapter 20. Breeding and QTL mapping for γ-oryzanol and nutrition content in rice.- Chapter 21. Genetic Enhancement of Nutritional Traits in Rice Grains through Marker Assisted Selection and Quantitative Trait Loci.- Chapter 22. Breeding approaches to generate biofortified rice for nutritional enhancement.-Chapter 23. Ameliorating nutritional, protein and vitamin content on rice seed through classic mating and advanced genetic technology.- Chapter 24: Genetic engineering of rice to fortify micronutrients.- Chapter 25. Golden Rice: genetic engineering, promises, present status and future prospects.- Chapter 26. Biofortification of rice with iron and zinc: progress and prospects.- Chapter 27. Biofortification of iron, zinc and selenium in rice for better quality.- Chapter 28. Micronutrient biofortification in rice for better quality.- Chapter 29. Rice Genetic Engineering for Increased Amino Acid and Vitamin Contents.- Chapter 30. Biofortification of iron, selenium and zinc in rice for quality improvement.- Chapter 31. Quantitative trait loci for rice grain quality improvement.- Chapter 32. Improvement of rice quality via biofortification of selenium, iron and zinc and its starring role in human health.- Chapter 33. Improvement of rice quality via biofortification of micronutrients.- Chapter 34. Involvement of policy makers, public acceptance and commercialization of nutritionally enhanced and genetically modified rice.-
Chapter 1. Understanding the mechanism of host-pathogen interaction in rice through genomics approaches.- Chapter 2. Genetic engineering and Genome editing strategies to enhance resistance of rice plants to diseases: a review of progress and future prospects.- Chapter 3: Transgenic rice live against bacterial blight.- Chapter 4. Genetic Engineering of Cultivated Rice for Viral Resistance.- Chapter 5. Genomics and genetic engineering for polyamine-mediated tolerance of rice against pathogen infection.- Chapter 6. Genomics and genetic engineering of rice for resistance to different insect pests.- Chapter 7. Genetic engineering of rice for resistance to insect pests.- Chapter 8. Increasing rice grain yield under biotic stresses: mutagenesis.- Chapter 9. Temporal and spatial dynamics of microbial communities in a genetically modified rice ecosystem.- Chapter 10. Genetic Engineering for Developing Herbicide Resistance in Rice Crops.- Chapter 11. An insight into the factors regulating flowering in rice: From genetics to epigenetics.- Chapter 12. Breeding and Bioengineering of male sterility in rice.- Chapter 13. Male sterility system for hybrid rice breeding and seed production.- Chapter 14. Advancement in tracking down nitrogen use efficiency in rice: Molecular breeding and genomics insight.- Chapter 15. Improving Water use Efficiency and Nitrogen use Efficiency in Rice through Breeding and Genomics Approaches.- Chapter 16. Rice breeding and genomics approaches for improving water and nitrogen use efficiency.- Chapter 17. Aromatic rice: biochemical and molecular basis of aroma production and stress response.- Chapter 18. Genomics and genetic engineering of rice elucidating cross-talk between stress signaling and nutrition enhancement via regulation of antioxidant, osmolyte and metabolite levels.- Chapter 19. Genetically modified rice stacked with antioxidants for nutrient enhancement and stress tolerance.- Chapter 20. Breeding and QTL mapping for Gamma-oryzanol and nutrition content in rice.- Chapter 21. Genetic Enhancement of Nutritional Traits in Rice Grains through Marker Assisted Selection and Quantitative Trait Loci.- Chapter 22. Breeding approaches to generate biofortified rice for nutritional enhancement.-Chapter 23. Ameliorating nutritional, protein and vitamin content on rice seed through classic mating and advanced genetic technology.- Chapter 24: Genetic engineering of rice to fortify micronutrients.- Chapter 25. Golden Rice: genetic engineering, promises, present status and future prospects.- Chapter 26. Biofortification of rice with iron and zinc: progress and prospects.- Chapter 27. Biofortification of iron, zinc and selenium in rice for better quality.- Chapter 28. Micronutrient biofortification in rice for better quality.- Chapter 29. Rice Genetic Engineering for Increased Amino Acid and Vitamin Contents.- Chapter 30. Biofortification of iron, selenium and zinc in rice for quality improvement.- Chapter 31. Quantitative trait loci for rice grain quality improvement.- Chapter 32. Improvement of rice quality via biofortification of selenium, iron and zinc and its starring role in human health.- Chapter 33. Improvement of rice quality via biofortification of micronutrients.- Chapter 34. Involvement of policy makers, public acceptance and commercialization of nutritionally enhanced and genetically modified rice.-
Es gelten unsere Allgemeinen Geschäftsbedingungen: www.buecher.de/agb
Impressum
www.buecher.de ist ein Internetauftritt der buecher.de internetstores GmbH
Geschäftsführung: Monica Sawhney | Roland Kölbl | Günter Hilger
Sitz der Gesellschaft: Batheyer Straße 115 - 117, 58099 Hagen
Postanschrift: Bürgermeister-Wegele-Str. 12, 86167 Augsburg
Amtsgericht Hagen HRB 13257
Steuernummer: 321/5800/1497