Plant micronutrient use efficiency : molecular and genomic perspectives in crop plants /: molecular and genomic perspectives in crop plants. ([2018])
- Record Type:
- Book
- Title:
- Plant micronutrient use efficiency : molecular and genomic perspectives in crop plants /: molecular and genomic perspectives in crop plants. ([2018])
- Main Title:
- Plant micronutrient use efficiency : molecular and genomic perspectives in crop plants
- Further Information:
- Note: [edited by] Mohammad Anwar Hossain, Takehiro Kamiya, David J. Burritt, Lam-Son Phan Tran, Toru Fujiwara.
- Editors:
- Hossain, Mohammad Anwar
Kamiya, Takehiro, 1944-
Burritt, David J
Tran, Lam-son Phan
Fujiwara, Tōru - Contents:
- Front Cover; Plant Micronutrient Use Efficiency: Molecular and Genomic Perspectives in Crop Plants; Copyright; Contents; Contributors; Editors' Biography; Preface; Acknowledgments; Chapter 1: Regulation of Micronutrient Homeostasis and Deficiency Response in Plants; 1 Introduction; 2 Iron; 2.1 Acquisition from Soil; 2.2 Regulation of Fe Homeostasis and Deficiency Response; 3 Copper; 3.1 Acquisition from Soil; 3.2 Regulation of Cu Homeostasis and Deficiency Response; 4 Zinc; 4.1 Acquisition from Soil; 4.2 Regulation of Zn Homeostasis and Deficiency Response; 5 Concluding Remarks; References Chapter 2: Molecular Bases of Iron Accumulation Towards the Development of Iron-Enriched Crops1 Introduction; 2 Iron Uptake From The Soil, Transport, and Storage in Roots; 2.1 Iron Uptake in Crops; 2.2 Strategy I, Strategy II, and a Combined Strategy; 2.3 Root Plasma Membrane Fe Transport; 2.4 Iron Chelation and Solubilization at the Rhizosphere; 2.5 Vacuolar Fe Storage in Roots; 2.6 Transcriptional Control of Fe Uptake; 3 Long Distance Fe Transport; 3.1 Root-to-Shoot Xylem-Dependent Fe Transport; 3.2 Iron Movement in the Phloem; 3.3 The Role of NA in Fe Seed Loading 3.4 Subcellular Fe Transport3.4.1 Vacuole; 3.4.2 Chloroplast; 3.4.3 Mitochondria; 4 Iron Distribution in Seeds; 5 Different Transgenic Strategies Used to Develop Fe-Enriched Plants; 6 Future Strategies to Develop Fe-Enriched Crops; References; Further Reading; Chapter 3: Plant Responses to Iron Deficiency and Toxicity and IronFront Cover; Plant Micronutrient Use Efficiency: Molecular and Genomic Perspectives in Crop Plants; Copyright; Contents; Contributors; Editors' Biography; Preface; Acknowledgments; Chapter 1: Regulation of Micronutrient Homeostasis and Deficiency Response in Plants; 1 Introduction; 2 Iron; 2.1 Acquisition from Soil; 2.2 Regulation of Fe Homeostasis and Deficiency Response; 3 Copper; 3.1 Acquisition from Soil; 3.2 Regulation of Cu Homeostasis and Deficiency Response; 4 Zinc; 4.1 Acquisition from Soil; 4.2 Regulation of Zn Homeostasis and Deficiency Response; 5 Concluding Remarks; References Chapter 2: Molecular Bases of Iron Accumulation Towards the Development of Iron-Enriched Crops1 Introduction; 2 Iron Uptake From The Soil, Transport, and Storage in Roots; 2.1 Iron Uptake in Crops; 2.2 Strategy I, Strategy II, and a Combined Strategy; 2.3 Root Plasma Membrane Fe Transport; 2.4 Iron Chelation and Solubilization at the Rhizosphere; 2.5 Vacuolar Fe Storage in Roots; 2.6 Transcriptional Control of Fe Uptake; 3 Long Distance Fe Transport; 3.1 Root-to-Shoot Xylem-Dependent Fe Transport; 3.2 Iron Movement in the Phloem; 3.3 The Role of NA in Fe Seed Loading 3.4 Subcellular Fe Transport3.4.1 Vacuole; 3.4.2 Chloroplast; 3.4.3 Mitochondria; 4 Iron Distribution in Seeds; 5 Different Transgenic Strategies Used to Develop Fe-Enriched Plants; 6 Future Strategies to Develop Fe-Enriched Crops; References; Further Reading; Chapter 3: Plant Responses to Iron Deficiency and Toxicity and Iron Use Efficiency in Plants; 1 Introduction; 2 Iron Deficiency Root Responses; 2.1 Strategy 1: Reduction-Based Fe Uptake; 2.2 Strategy 2: Chelation-Based Fe Uptake; 2.3 Coexistence of Reduction and Chelation Strategies; 3 Iron Toxicity Responses 4 Long-Distance Fe Transport4.1 Xylem Transport; 4.2 Phloem Transport; 4.3 Xylem-to-Phloem Lateral Fe Transfer in Shoots; 5 Subcellular Fe Transport and Compartmentation; 6 Regulation of Fe Use Efficiency; 6.1 Efficient Vs Inefficient Genotypes; 6.2 Candidate for Fe Sensors and Signals; 6.3 Crosstalk Between Fe and Other Elements; 7 Conclusion and Prospects; Acknowledgments; References; Chapter 4: Plant Responses to Copper: Molecular and Regulatory Mechanisms of Copper Uptake, Distribution and Accumulation i...; 1 Copper Properties and Functions in Plants 2 Copper Phytoavailability and Bioavailability3 Uptake, Distribution and Accumulation of Cu By Plants; 3.1 Copper Uptake; 3.2 Copper Transport Into Chloroplasts and Mitochondria; 3.3 Copper Transport Through the Secretory Pathway; 3.4 Copper Transport Into and Out of the Vacuole; 3.5 Long-Distance Cu Transport from Roots to Shoots; 3.6 Copper Remobilization from Senescing Organs; 4 Molecular Responses to Cu Deficiency in Plants; 5 The Increase of Cu Uptake and Accumulation Efficiency in Plants: Prospects for Biofortification of Crops; References; Further Reading … (more)
- Publisher Details:
- London, United Kingdom San Diego, CA : Academic Press
- Publication Date:
- 2018
- Extent:
- 1 online resource
- Subjects:
- 572/.42
Plants -- Nutrition
Crops -- Nutrition
Trace elements
SCIENCE / Life Sciences / Biochemistry
Electronic books - Languages:
- English
- ISBNs:
- 9780128122433
0128122439 - Related ISBNs:
- 9780128121047
- Notes:
- Note: Includes bibliographical references and index.
Note: Online resource; title from PDF title page (EBSCO, viewed March 28, 2018). - Access Rights:
- Legal Deposit; Only available on premises controlled by the deposit library and to one user at any one time; The Legal Deposit Libraries (Non-Print Works) Regulations (UK).
- Access Usage:
- Restricted: Printing from this resource is governed by The Legal Deposit Libraries (Non-Print Works) Regulations (UK) and UK copyright law currently in force.
- View Content:
- Available online (eLD content is only available in our Reading Rooms) ↗
- Physical Locations:
- British Library HMNTS - ELD.DS.274644
- Ingest File:
- 01_177.xml