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Approaches in Enhancing Antioxidant Defense in Plants
| Approaches in Enhancing Antioxidant Defense in Plants |
| Autore | Fujita Masayuki |
| Pubbl/distr/stampa | Basel, : MDPI - Multidisciplinary Digital Publishing Institute, 2022 |
| Descrizione fisica | 1 electronic resource (370 p.) |
| Soggetto topico |
Research & information: general
Biology, life sciences |
| Soggetto non controllato |
melatonin
water stress drought waterlogging abiotic stress antioxidants stress signaling phytohormones antioxidant biomolecules climate change reactive oxygen species halophytes soil salinity signaling molecules molybdenum cadmium stress photosynthetic pigments oxidative damage quality characters fragrant rice brassinosteroids chromium heavy metals rice adaptability heat stress water homeostasis hormone stoma transpiration antioxidant defense systems gene ontology miRNA 3D structures methyl jasmonate photosystem Brassica napus salinity stress antioxidant enzymes osmolytes ROS metabolites antioxidant defence ascorbate glutathione microspore embryogenesis Hordeum vulgare ×Triticosecale Wittm nitric oxide iron-deficiency chlorosis alfalfa chilling legumes pollen stigma acclimatization stress Cr+6 bioremediation improved antioxidant activity plant growth promotion rhizobacteria superoxide dismutase potato AlphaFold salicylic acid Glycine max seed germination photosynthesis secondary metabolites salinity |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNINA-9910576885003321 |
Fujita Masayuki
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| Basel, : MDPI - Multidisciplinary Digital Publishing Institute, 2022 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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Ascorbic Acid in Plant Growth, Development and Stress Tolerance / / edited by Mohammad Anwar Hossain, Sergi Munné-Bosch, David J. Burritt, Pedro Diaz-Vivancos, Masayuki Fujita, Argelia Lorence
| Ascorbic Acid in Plant Growth, Development and Stress Tolerance / / edited by Mohammad Anwar Hossain, Sergi Munné-Bosch, David J. Burritt, Pedro Diaz-Vivancos, Masayuki Fujita, Argelia Lorence |
| Edizione | [1st ed. 2017.] |
| Pubbl/distr/stampa | Cham : , : Springer International Publishing : , : Imprint : Springer, , 2017 |
| Descrizione fisica | 1 online resource (514 pages) |
| Disciplina | 581.1926 |
| Soggetto topico |
Agriculture
Plant physiology Plant breeding Nutrition Plant Physiology Plant Breeding/Biotechnology Nutrition |
| ISBN | 3-319-74057-1 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | 1 Chemistry, biosynthesis and oxidation of ascorbic acid in plants -- 2 The roles of ascorbate in the control of plant growth and development -- 3 Ascorbate transporter in plants -- 4 Ascorbate as a key player in plant abiotic stress response and tolerance -- 5 Ascorbate peroxidases: emerging role of the antioxidant enzymes in plant development and stress responses -- 6 Molecular structure of DHAR and MDHAR and their roles in modulating abiotic stress tolerance in plants -- 7 Triad of low molecular weight antioxidants (GSH-AsA-α-tocopherol) in plant abiotic stress response and tolerance -- 8 Regulation of ascorbate biosynthesis in plants -- 9 Ascorbate-glutathione cycle and abiotic stress tolerance in plants -- 10 Ascorbate-glutathione cycle and biotic stress tolerance in plants -- 11 Exogenous ascorbic acid mediated abiotic stress tolerance in plants -- 12 Ascorbic acid and biotic stress tolerance in plants -- 13 Ascorbate oxidase in plant growth, development and stress tolerance -- 14 Relationship between AsA biosynthesis and stress defense gene expression in plants -- 15 AsA/DHA redox pair and stress responsive gene expression -- 16 Ascorbic acid and insect resistance in plants -- 17 Transgenic plants over-expressing AsA biosynthetic genes and abiotic stress tolerance -- 18 MDHAR and DHAR transgenic and AsA content and abiotic stress tolerance -- 19 Biofortification of crops with altered AsA content -- 20 Genetic control of fruit vitamin c contents -- 21 Importance of vitamin-C in human health and disease. |
| Record Nr. | UNINA-9910279577103321 |
| Cham : , : Springer International Publishing : , : Imprint : Springer, , 2017 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Biostimulants for Crop Production and Sustainable Agriculture
| Biostimulants for Crop Production and Sustainable Agriculture |
| Autore | Hasanuzzaman Mirza |
| Pubbl/distr/stampa | Oxford : , : CAB International, , 2022 |
| Descrizione fisica | 1 online resource (701 pages) |
| Disciplina | 631.8 |
| Altri autori (Persone) |
Hawrylak-NowakBarbara
IslamTofazzal FujitaMasayuki |
| Soggetto topico |
Plant growth promoting substances
Sustainable agriculture Growth (Plants) |
| ISBN |
1-78924-808-6
1-78924-809-4 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNINA-9910760495503321 |
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Hasanuzzaman Mirza
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| Oxford : , : CAB International, , 2022 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Glutathione in Plant Growth, Development, and Stress Tolerance / / edited by Mohammad Anwar Hossain, Mohammad Golam Mostofa, Pedro Diaz-Vivancos, David J Burritt, Masayuki Fujita, Lam-Son Phan Tran
| Glutathione in Plant Growth, Development, and Stress Tolerance / / edited by Mohammad Anwar Hossain, Mohammad Golam Mostofa, Pedro Diaz-Vivancos, David J Burritt, Masayuki Fujita, Lam-Son Phan Tran |
| Edizione | [1st ed. 2017.] |
| Pubbl/distr/stampa | Cham : , : Springer International Publishing : , : Imprint : Springer, , 2017 |
| Descrizione fisica | 1 online resource (XII, 421 p. 46 illus., 39 illus. in color.) |
| Disciplina | 572.65 |
| Soggetto topico |
Plant physiology
Agriculture Gene expression Oxidative stress Plant Physiology Gene Expression Oxidative Stress |
| ISBN | 3-319-66682-7 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNINA-9910253955903321 |
| Cham : , : Springer International Publishing : , : Imprint : Springer, , 2017 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Heavy Metal Toxicity and Tolerance in Plants : A Biological, Omics, and Genetic Engineering Approach
| Heavy Metal Toxicity and Tolerance in Plants : A Biological, Omics, and Genetic Engineering Approach |
| Autore | Hossain Mohammad Anwar |
| Edizione | [1st ed.] |
| Pubbl/distr/stampa | Newark : , : John Wiley & Sons, Incorporated, , 2023 |
| Descrizione fisica | 1 online resource (643 pages) |
| Altri autori (Persone) |
HossainA. K. M. Zakir
BourgerieSylvain FujitaMasayuki DhankherOm Parkash HarisParvez |
| ISBN |
1-119-90650-4
1-119-90647-4 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Cover -- Title Page -- Copyright Page -- Contents -- List of Contributors -- Preface -- Editor Biographies -- Chapter 1 Plant Response and Tolerance to Heavy Metal Toxicity: An Overview of Chemical Biology, Omics Studies, and Genetic Engineering -- 1.1 Introduction -- 1.2 Plant-Metal Interaction -- 1.3 Effect of Heavy Metals on Plants -- 1.3.1 Morphoanatomical Responses -- 1.3.2 Physiological Responses -- 1.3.3 Biochemical Responses -- 1.3.4 Molecular Responses -- 1.4 Mechanisms to Tolerate Heavy Metal Toxicity -- 1.4.1 Avoidance -- 1.4.2 Sequestration -- 1.5 Important Strategies for the Enhancement of Metal Tolerance -- 1.5.1 Omics -- 1.5.2 Genetic Engineering -- 1.6 Conclusion and Future Prospects -- References -- Chapter 2 Advanced Techniques in Omics Research in Relation to Heavy Metal/Metalloid Toxicity and Tolerance in Plants -- 2.1 Introduction -- 2.2 An Overview of Plant Responses to Heavy Metal Toxicity -- 2.3 How the Integration of Multi-omics Data Sets Helps in Studying the Heavy Metal Stress Responses and Tolerance Mechanisms? -- 2.3.1 The Contribution of State-of-the-Art Genomics-Assisted Breeding -- 2.3.2 Transcriptomics -- 2.3.3 Proteomics -- 2.3.4 Metabolomics -- 2.3.5 miRNAomics -- 2.3.6 Phenomics -- 2.4 Conclusion and Perspectives -- References -- Chapter 3 Heavy Metals/Metalloids in Food Crops and Their Implications for Human Health -- 3.1 Introduction -- 3.2 Arsenic -- 3.2.1 Sources and Forms -- 3.2.2 Food Chain Contamination -- 3.2.3 Pharmacokinetic Processes -- 3.2.4 Toxicology Processes -- 3.2.5 Remedial Options -- 3.3 Cadmium -- 3.3.1 Sources and Forms -- 3.3.2 Food Chain Contamination -- 3.3.3 Pharmacokinetic Processes -- 3.3.4 Toxicology Processes -- 3.3.5 Remedial Options -- 3.4 Lead -- 3.4.1 Sources and Forms -- 3.4.2 Food Chain Contamination -- 3.4.3 Pharmacokinetic Processes -- 3.4.4 Toxicology Processes.
3.4.5 Remedial Options -- 3.5 Chromium -- 3.5.1 Sources and Forms -- 3.5.2 Food Chain Contamination -- 3.5.3 Pharmacokinetic Processes -- 3.5.4 Toxicology Processes -- 3.5.5 Remedial Options -- 3.6 Mercury -- 3.6.1 Sources and Forms -- 3.6.2 Food Chain Contamination -- 3.6.3 Pharmacokinetic Processes -- 3.6.4 Toxicology Processes -- 3.6.5 Remedial Options -- 3.7 Conclusions -- References -- Chapter 4 Aluminum Stress Tolerance in Plants: Insights from Omics Approaches -- 4.1 Introduction -- 4.2 Exploration of Al Tolerance QTLs -- 4.3 Unraveling the Genetic Architecture of Al Tolerance from Natural Variation -- 4.4 Identification of Novel Al Tolerance Genes Through Genome-Wide Association Studies -- 4.5 Exploring Expression Level Polymorphisms to Identify Upstream Al Signaling -- 4.6 Comparative Transcriptome Analyses Identify Novel Al Tolerance Genes -- 4.7 Identification of Al Tolerance Genes from Proteomics -- 4.8 Conclusion and Future Perspectives -- References -- Chapter 5 Breeding Approaches for Aluminum Toxicity Tolerance in Rice and Wheat -- 5.1 Introduction -- 5.2 Plant Signaling -- 5.3 Rice Genetic Mapping -- 5.3.1 Linkage Mapping -- 5.3.2 Association Mapping -- 5.4 Root Transcriptome -- 5.5 Wheat Genetic Mapping -- 5.5.1 Wheat MATE Gene Family -- 5.6 Wheat Proteomics -- 5.7 Conclusion -- References -- Chapter 6 Chromium Toxicity and Tolerance in Plants: Insights from Omics Studies -- 6.1 Introduction -- 6.2 Chromium Sources and Bioavailability -- 6.3 Chromium Uptake, Translocation, and Sub-cellular Distribution in Plants -- 6.4 Detoxification Mechanisms for Cr -- 6.5 Omics Approaches Used by Plants to Combat Cr Toxicity -- 6.5.1 Transcriptomics -- 6.5.2 Chromium-Induced miRNAs in Plants -- 6.5.3 Metabolomics -- 6.5.4 Proteomics -- 6.6 Phytoremediation of Cr Metal by Plants -- 6.6.1 Phytoremediation Approach for Cr Detoxification. 6.6.2 Other Strategies Involved in Cr Remediation -- 6.6.3 Phytostabilization/Phytoextraction for Cr Decontamination -- 6.7 Conclusion -- References -- Chapter 7 Manganese Toxicity and Tolerance in Photosynthetic Organisms and Breeding Strategy for Improving Manganese Tolerance in Crop Plants: Physiological and Omics Approach Perspectives -- 7.1 Introduction -- 7.2 The Change in Mn Availability Within the Soil -- 7.3 Why Should We Consider the Occurrence of Mn Toxicity in Plants? Possible Threats of Mn Toxicity in Agricultural Land -- 7.4 The History of Mn Toxicity -- 7.5 The Features of Mn Toxicity in Terrestrial Plants and Possible Molecular Mechanisms -- 7.5.1 The Mechanisms of Emergence of Brownish Patchy Spots in Leaves: The Apoplastic Mn Toxicity -- 7.5.2 The Mechanisms of Foliar Chlorosis Under Excess Mn: Symplastic Mn Toxicity -- 7.6 Breeding Strategy for Overcoming the Future Threat of Excess Mn Conditions -- 7.6.1 Limiting Mn Absorption from Soil to Root -- 7.6.2 Sequestration of Mn from Cytosol to the Vacuole or Apoplast -- 7.6.3 Maintenance of Auxin Homeostasis -- 7.6.4 The Reinforcement of Silicon Uptake and Its Distribution -- 7.7 Conclusion and Future Prospects -- Acknowledgments -- References -- Chapter 8 Iron Excess Toxicity and Tolerance in Crop Plants: Insights from Omics Studies -- 8.1 Iron Uptake and Translocation Mechanism in Plants -- 8.1.1 Importance of Iron in Living Organisms -- 8.1.2 Fe Acquisition Systems in Plants -- 8.1.3 Fe Translocation Mechanisms in Plants -- 8.2 Fe Excess Toxicity in Plants -- 8.2.1 Fe Excess Toxicity in Global Agriculture -- 8.2.2 Causes of Fe Excess Toxicity in Soils and Its Interaction with Plants -- 8.2.3 Effects of Fe Excess Toxicity on Plant Growth -- 8.3 Crop Defense Mechanisms Against Excess Fe and Genes Regulating Fe Excess -- 8.3.1 Defense I: Fe Exclusion from Roots. 8.3.2 Defense II: Fe Retention in Roots and Suppression of Fe Translocation to Shoots -- 8.3.3 Defense III: Fe Compartmentalization in Shoots -- 8.3.4 Defense IV: ROS Detoxification -- 8.4 Research Outlook on Fe Excess Response of Plants -- 8.4.1 Regulation of Fe homeostasis in Plants in Response to Fe Excess Stress -- 8.4.2 Transcription Factors -- 8.4.3 Cis-Regulatory Elements -- 8.5 Conclusion and Future Prospects -- Acknowledgments -- Author Contributions -- Disclosures -- References -- Chapter 9 Molecular Breeding for Iron Toxicity Tolerance in Rice (Oryza sativa L.) -- 9.1 Introduction -- 9.2 Role of Iron in Plants and Rice -- 9.3 Iron Toxicity and Its Effects on Rice -- 9.4 Iron Toxicity Tolerance Mechanisms in Rice Plants -- 9.4.1 Fe Exclusion from Roots -- 9.4.2 Fe Retention in Roots and Suppression of Fe Translocation to Shoots -- 9.4.3 Fe Compartmentalization in Shoots -- 9.4.4 ROS Detoxification -- 9.4.5 Candidate Genes Involved in the Mechanisms of Fe Toxicity -- 9.4.6 Genetic Variants for Iron Toxicity Tolerance in Rice Germplasm -- 9.5 Molecular Breeding for Fe Toxicity Tolerance in Rice -- 9.6 Conclusion -- References -- Chapter 10 Cobalt Induced Toxicity and Tolerance in Plants: Insights from Omics Approaches -- 10.1 Introduction -- 10.2 Plant Response to Cobalt Stress -- 10.2.1 Uptake and Translocation of Cobalt in Plants -- 10.3 Cobalt-Induced ROS Generation and Their Damaging Effects -- 10.3.1 ROS-Induced Lipid Peroxidation -- 10.3.2 ROS-Induced Damage to Genetic Material -- 10.4 Cobalt-Induced Plant Antioxidant Defense System -- 10.4.1 Enzymatic Antioxidants -- 10.4.2 Nonenzymatic Antioxidants -- 10.5 Omics Approaches in Cobalt Stress Tolerance -- 10.5.1 Transcriptomic -- 10.5.2 Metabolomics -- 10.5.3 Proteomics -- 10.6 Conclusion and Future Prospects -- Acknowledgments -- References. Chapter 11 Nickel Toxicity and Tolerance in Plants -- 11.1 Introduction -- 11.2 Sources of Ni -- 11.2.1 Natural Sources of Ni -- 11.2.2 Anthropogenic Sources of Ni -- 11.3 Role of Ni in Plants -- 11.4 Ni Uptake and Accumulation in Plants -- 11.5 Ni Toxicity in Plants -- 11.5.1 Growth Inhibition -- 11.5.2 Photosynthesis Inhibition of Ni -- 11.5.3 Induction of Oxidative Stress -- 11.6 Tolerance Mechanisms -- 11.7 Omics Approaches in Ni Stress Tolerance -- 11.7.1 Transcriptomics -- 11.7.2 Proteomics -- 11.7.3 Metabolomics -- 11.8 Conclusion -- References -- Chapter 12 Copper Toxicity and Tolerance in Plants: Insights from Omics Studies -- 12.1 Introduction -- 12.2 Copper in Plants -- 12.2.1 Functions of Copper -- 12.2.2 Uptake, Transport, Distribution, and Remobilization Mechanisms -- 12.2.3 Deficient, Sufficient, and Toxic Levels of Copper in Plants -- 12.2.4 Copper Sources: Fertilizers and Fungicides -- 12.3 Omics Approaches for Cu Responses and Tolerance in Plants -- 12.3.1 Genomics -- 12.3.2 Transcriptomics -- 12.3.3 Proteomics -- 12.3.4 Metabolomics -- 12.3.5 miRNAomics -- 12.4 Concluding Remarks -- Acknowledgments -- References -- Chapter 13 Zinc Toxicity and Tolerance in Plants: Insights from Omics Studies -- 13.1 Introduction -- 13.1.1 Zinc Uptake and Translocation Mechanisms in Plants -- 13.1.2 Transporters and Metal-Binding Compounds Involved in Zinc Homeostasis -- 13.2 Impact of Excess Zinc on Physio-genetics Aspects of Plants -- 13.2.1 Effect of Zinc Toxicity on Seed Germination and Growth of Plants -- 13.2.2 Effect of Zinc Toxicity on Oxidative Metabolism in Plants -- 13.2.3 Effect of Zn Toxicity on Physiology and Biochemistry of Plants -- 13.3 Plants Stress Adaptation to Zinc Toxicity -- 13.4 Multi-omics Approaches for Zinc Toxicity and Tolerance in Plants -- 13.4.1 Genomics and Metabolomics -- 13.4.2 Proteomics and Transcriptomics. 13.4.3 miRNA Omics and CRISPR/Cas9 System. |
| Record Nr. | UNINA-9910830635903321 |
|
Hossain Mohammad Anwar
|
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| Newark : , : John Wiley & Sons, Incorporated, , 2023 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Heavy Metal Toxicity and Tolerance in Plants : A Biological, Omics, and Genetic Engineering Approach
| Heavy Metal Toxicity and Tolerance in Plants : A Biological, Omics, and Genetic Engineering Approach |
| Autore | Hossain Mohammad Anwar |
| Edizione | [1st ed.] |
| Pubbl/distr/stampa | Newark : , : John Wiley & Sons, Incorporated, , 2023 |
| Descrizione fisica | 1 online resource (643 pages) |
| Altri autori (Persone) |
HossainA. K. M. Zakir
BourgerieSylvain FujitaMasayuki DhankherOm Parkash HarisParvez |
| ISBN |
1-119-90650-4
1-119-90647-4 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Cover -- Title Page -- Copyright Page -- Contents -- List of Contributors -- Preface -- Editor Biographies -- Chapter 1 Plant Response and Tolerance to Heavy Metal Toxicity: An Overview of Chemical Biology, Omics Studies, and Genetic Engineering -- 1.1 Introduction -- 1.2 Plant-Metal Interaction -- 1.3 Effect of Heavy Metals on Plants -- 1.3.1 Morphoanatomical Responses -- 1.3.2 Physiological Responses -- 1.3.3 Biochemical Responses -- 1.3.4 Molecular Responses -- 1.4 Mechanisms to Tolerate Heavy Metal Toxicity -- 1.4.1 Avoidance -- 1.4.2 Sequestration -- 1.5 Important Strategies for the Enhancement of Metal Tolerance -- 1.5.1 Omics -- 1.5.2 Genetic Engineering -- 1.6 Conclusion and Future Prospects -- References -- Chapter 2 Advanced Techniques in Omics Research in Relation to Heavy Metal/Metalloid Toxicity and Tolerance in Plants -- 2.1 Introduction -- 2.2 An Overview of Plant Responses to Heavy Metal Toxicity -- 2.3 How the Integration of Multi-omics Data Sets Helps in Studying the Heavy Metal Stress Responses and Tolerance Mechanisms? -- 2.3.1 The Contribution of State-of-the-Art Genomics-Assisted Breeding -- 2.3.2 Transcriptomics -- 2.3.3 Proteomics -- 2.3.4 Metabolomics -- 2.3.5 miRNAomics -- 2.3.6 Phenomics -- 2.4 Conclusion and Perspectives -- References -- Chapter 3 Heavy Metals/Metalloids in Food Crops and Their Implications for Human Health -- 3.1 Introduction -- 3.2 Arsenic -- 3.2.1 Sources and Forms -- 3.2.2 Food Chain Contamination -- 3.2.3 Pharmacokinetic Processes -- 3.2.4 Toxicology Processes -- 3.2.5 Remedial Options -- 3.3 Cadmium -- 3.3.1 Sources and Forms -- 3.3.2 Food Chain Contamination -- 3.3.3 Pharmacokinetic Processes -- 3.3.4 Toxicology Processes -- 3.3.5 Remedial Options -- 3.4 Lead -- 3.4.1 Sources and Forms -- 3.4.2 Food Chain Contamination -- 3.4.3 Pharmacokinetic Processes -- 3.4.4 Toxicology Processes.
3.4.5 Remedial Options -- 3.5 Chromium -- 3.5.1 Sources and Forms -- 3.5.2 Food Chain Contamination -- 3.5.3 Pharmacokinetic Processes -- 3.5.4 Toxicology Processes -- 3.5.5 Remedial Options -- 3.6 Mercury -- 3.6.1 Sources and Forms -- 3.6.2 Food Chain Contamination -- 3.6.3 Pharmacokinetic Processes -- 3.6.4 Toxicology Processes -- 3.6.5 Remedial Options -- 3.7 Conclusions -- References -- Chapter 4 Aluminum Stress Tolerance in Plants: Insights from Omics Approaches -- 4.1 Introduction -- 4.2 Exploration of Al Tolerance QTLs -- 4.3 Unraveling the Genetic Architecture of Al Tolerance from Natural Variation -- 4.4 Identification of Novel Al Tolerance Genes Through Genome-Wide Association Studies -- 4.5 Exploring Expression Level Polymorphisms to Identify Upstream Al Signaling -- 4.6 Comparative Transcriptome Analyses Identify Novel Al Tolerance Genes -- 4.7 Identification of Al Tolerance Genes from Proteomics -- 4.8 Conclusion and Future Perspectives -- References -- Chapter 5 Breeding Approaches for Aluminum Toxicity Tolerance in Rice and Wheat -- 5.1 Introduction -- 5.2 Plant Signaling -- 5.3 Rice Genetic Mapping -- 5.3.1 Linkage Mapping -- 5.3.2 Association Mapping -- 5.4 Root Transcriptome -- 5.5 Wheat Genetic Mapping -- 5.5.1 Wheat MATE Gene Family -- 5.6 Wheat Proteomics -- 5.7 Conclusion -- References -- Chapter 6 Chromium Toxicity and Tolerance in Plants: Insights from Omics Studies -- 6.1 Introduction -- 6.2 Chromium Sources and Bioavailability -- 6.3 Chromium Uptake, Translocation, and Sub-cellular Distribution in Plants -- 6.4 Detoxification Mechanisms for Cr -- 6.5 Omics Approaches Used by Plants to Combat Cr Toxicity -- 6.5.1 Transcriptomics -- 6.5.2 Chromium-Induced miRNAs in Plants -- 6.5.3 Metabolomics -- 6.5.4 Proteomics -- 6.6 Phytoremediation of Cr Metal by Plants -- 6.6.1 Phytoremediation Approach for Cr Detoxification. 6.6.2 Other Strategies Involved in Cr Remediation -- 6.6.3 Phytostabilization/Phytoextraction for Cr Decontamination -- 6.7 Conclusion -- References -- Chapter 7 Manganese Toxicity and Tolerance in Photosynthetic Organisms and Breeding Strategy for Improving Manganese Tolerance in Crop Plants: Physiological and Omics Approach Perspectives -- 7.1 Introduction -- 7.2 The Change in Mn Availability Within the Soil -- 7.3 Why Should We Consider the Occurrence of Mn Toxicity in Plants? Possible Threats of Mn Toxicity in Agricultural Land -- 7.4 The History of Mn Toxicity -- 7.5 The Features of Mn Toxicity in Terrestrial Plants and Possible Molecular Mechanisms -- 7.5.1 The Mechanisms of Emergence of Brownish Patchy Spots in Leaves: The Apoplastic Mn Toxicity -- 7.5.2 The Mechanisms of Foliar Chlorosis Under Excess Mn: Symplastic Mn Toxicity -- 7.6 Breeding Strategy for Overcoming the Future Threat of Excess Mn Conditions -- 7.6.1 Limiting Mn Absorption from Soil to Root -- 7.6.2 Sequestration of Mn from Cytosol to the Vacuole or Apoplast -- 7.6.3 Maintenance of Auxin Homeostasis -- 7.6.4 The Reinforcement of Silicon Uptake and Its Distribution -- 7.7 Conclusion and Future Prospects -- Acknowledgments -- References -- Chapter 8 Iron Excess Toxicity and Tolerance in Crop Plants: Insights from Omics Studies -- 8.1 Iron Uptake and Translocation Mechanism in Plants -- 8.1.1 Importance of Iron in Living Organisms -- 8.1.2 Fe Acquisition Systems in Plants -- 8.1.3 Fe Translocation Mechanisms in Plants -- 8.2 Fe Excess Toxicity in Plants -- 8.2.1 Fe Excess Toxicity in Global Agriculture -- 8.2.2 Causes of Fe Excess Toxicity in Soils and Its Interaction with Plants -- 8.2.3 Effects of Fe Excess Toxicity on Plant Growth -- 8.3 Crop Defense Mechanisms Against Excess Fe and Genes Regulating Fe Excess -- 8.3.1 Defense I: Fe Exclusion from Roots. 8.3.2 Defense II: Fe Retention in Roots and Suppression of Fe Translocation to Shoots -- 8.3.3 Defense III: Fe Compartmentalization in Shoots -- 8.3.4 Defense IV: ROS Detoxification -- 8.4 Research Outlook on Fe Excess Response of Plants -- 8.4.1 Regulation of Fe homeostasis in Plants in Response to Fe Excess Stress -- 8.4.2 Transcription Factors -- 8.4.3 Cis-Regulatory Elements -- 8.5 Conclusion and Future Prospects -- Acknowledgments -- Author Contributions -- Disclosures -- References -- Chapter 9 Molecular Breeding for Iron Toxicity Tolerance in Rice (Oryza sativa L.) -- 9.1 Introduction -- 9.2 Role of Iron in Plants and Rice -- 9.3 Iron Toxicity and Its Effects on Rice -- 9.4 Iron Toxicity Tolerance Mechanisms in Rice Plants -- 9.4.1 Fe Exclusion from Roots -- 9.4.2 Fe Retention in Roots and Suppression of Fe Translocation to Shoots -- 9.4.3 Fe Compartmentalization in Shoots -- 9.4.4 ROS Detoxification -- 9.4.5 Candidate Genes Involved in the Mechanisms of Fe Toxicity -- 9.4.6 Genetic Variants for Iron Toxicity Tolerance in Rice Germplasm -- 9.5 Molecular Breeding for Fe Toxicity Tolerance in Rice -- 9.6 Conclusion -- References -- Chapter 10 Cobalt Induced Toxicity and Tolerance in Plants: Insights from Omics Approaches -- 10.1 Introduction -- 10.2 Plant Response to Cobalt Stress -- 10.2.1 Uptake and Translocation of Cobalt in Plants -- 10.3 Cobalt-Induced ROS Generation and Their Damaging Effects -- 10.3.1 ROS-Induced Lipid Peroxidation -- 10.3.2 ROS-Induced Damage to Genetic Material -- 10.4 Cobalt-Induced Plant Antioxidant Defense System -- 10.4.1 Enzymatic Antioxidants -- 10.4.2 Nonenzymatic Antioxidants -- 10.5 Omics Approaches in Cobalt Stress Tolerance -- 10.5.1 Transcriptomic -- 10.5.2 Metabolomics -- 10.5.3 Proteomics -- 10.6 Conclusion and Future Prospects -- Acknowledgments -- References. Chapter 11 Nickel Toxicity and Tolerance in Plants -- 11.1 Introduction -- 11.2 Sources of Ni -- 11.2.1 Natural Sources of Ni -- 11.2.2 Anthropogenic Sources of Ni -- 11.3 Role of Ni in Plants -- 11.4 Ni Uptake and Accumulation in Plants -- 11.5 Ni Toxicity in Plants -- 11.5.1 Growth Inhibition -- 11.5.2 Photosynthesis Inhibition of Ni -- 11.5.3 Induction of Oxidative Stress -- 11.6 Tolerance Mechanisms -- 11.7 Omics Approaches in Ni Stress Tolerance -- 11.7.1 Transcriptomics -- 11.7.2 Proteomics -- 11.7.3 Metabolomics -- 11.8 Conclusion -- References -- Chapter 12 Copper Toxicity and Tolerance in Plants: Insights from Omics Studies -- 12.1 Introduction -- 12.2 Copper in Plants -- 12.2.1 Functions of Copper -- 12.2.2 Uptake, Transport, Distribution, and Remobilization Mechanisms -- 12.2.3 Deficient, Sufficient, and Toxic Levels of Copper in Plants -- 12.2.4 Copper Sources: Fertilizers and Fungicides -- 12.3 Omics Approaches for Cu Responses and Tolerance in Plants -- 12.3.1 Genomics -- 12.3.2 Transcriptomics -- 12.3.3 Proteomics -- 12.3.4 Metabolomics -- 12.3.5 miRNAomics -- 12.4 Concluding Remarks -- Acknowledgments -- References -- Chapter 13 Zinc Toxicity and Tolerance in Plants: Insights from Omics Studies -- 13.1 Introduction -- 13.1.1 Zinc Uptake and Translocation Mechanisms in Plants -- 13.1.2 Transporters and Metal-Binding Compounds Involved in Zinc Homeostasis -- 13.2 Impact of Excess Zinc on Physio-genetics Aspects of Plants -- 13.2.1 Effect of Zinc Toxicity on Seed Germination and Growth of Plants -- 13.2.2 Effect of Zinc Toxicity on Oxidative Metabolism in Plants -- 13.2.3 Effect of Zn Toxicity on Physiology and Biochemistry of Plants -- 13.3 Plants Stress Adaptation to Zinc Toxicity -- 13.4 Multi-omics Approaches for Zinc Toxicity and Tolerance in Plants -- 13.4.1 Genomics and Metabolomics -- 13.4.2 Proteomics and Transcriptomics. 13.4.3 miRNA Omics and CRISPR/Cas9 System. |
| Record Nr. | UNINA-9910841027503321 |
|
Hossain Mohammad Anwar
|
||
| Newark : , : John Wiley & Sons, Incorporated, , 2023 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Mechanisms of Arsenic Toxicity and Tolerance in Plants [[electronic resource] /] / edited by Mirza Hasanuzzaman, Kamrun Nahar, Masayuki Fujita
| Mechanisms of Arsenic Toxicity and Tolerance in Plants [[electronic resource] /] / edited by Mirza Hasanuzzaman, Kamrun Nahar, Masayuki Fujita |
| Edizione | [1st ed. 2018.] |
| Pubbl/distr/stampa | Singapore : , : Springer Singapore : , : Imprint : Springer, , 2018 |
| Descrizione fisica | 1 online resource (xv, 508 pages) |
| Disciplina | 571.742 |
| Soggetto topico |
Plant physiology
Soil conservation Agriculture Biochemistry Plant Physiology Soil Science & Conservation Plant Biochemistry |
| ISBN | 981-13-1292-3 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | 1 Arsenic Uptake and Transportation in Plants -- 2. Plant Responses to Arsenic Toxicity: Morphology and physiology -- 3. Consequences of Paddy Cultivation in Arsenic Contaminated Paddy Fields of Lower Indo-Gangetic Plane on Arsenic Accumulation Pattern and Selected Grain Quality Traits: A Preliminary Assessment -- 4.Arsenic-induced Oxidative Stress in Plants -- 5. Plants Response and Tolerance to Arsenic-induced oxidative Stress -- 6. Arsenic Toxicity in Crop Plants: Responses and Remediation Strategies -- 7. Plant’s Adaptive Mechanisms Under Arsenic Pollution -- 8. Mitigating Arsenic Toxicity in Plants: Role of Microbiota -- 9. Role of Plant-Microorganism Interactions in Plant Tolerance to Arsenic -- 10. Interaction of Plants and Arbuscular Mycorrhizal Fungi in Responses to Arsenic Stress: A Collaborative Tale Useful to Manage Contaminated Soil -- 11. Potentials of Aquatic Plants and Algae for Arsenic Accumulation -- 12. Algae as a Budding Tool for Mitigation of Arsenic from Aquatic Systems -- 13. A Glimpse on Uptake Kinetics and Molecular Responses of Arsenic Tolerance in Rice Plants -- 14. Transcriptomics of Arsenic Tolerance in Plants -- 15. Agronomics Management for Arsenic Stress Mitigation. 16.Environmental Chemistry, Fate and Speciation of Arsenic in Groundwater-Soil-Crop Systems -- 17. Treatment of Arsenic Contaminated Water: Mechanism of Treatment Methods -- 18. Status of Arsenic Toxicity in the World -- 19. Arsenic toxicity: A South Asian perspective. |
| Record Nr. | UNINA-9910739474503321 |
| Singapore : , : Springer Singapore : , : Imprint : Springer, , 2018 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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Osmoprotectant-Mediated Abiotic Stress Tolerance in Plants : Recent Advances and Future Perspectives / / edited by Mohammad Anwar Hossain, Vinay Kumar, David J. Burritt, Masayuki Fujita, Pirjo S. A. Mäkelä
| Osmoprotectant-Mediated Abiotic Stress Tolerance in Plants : Recent Advances and Future Perspectives / / edited by Mohammad Anwar Hossain, Vinay Kumar, David J. Burritt, Masayuki Fujita, Pirjo S. A. Mäkelä |
| Edizione | [1st ed. 2019.] |
| Pubbl/distr/stampa | Cham : , : Springer International Publishing : , : Imprint : Springer, , 2019 |
| Descrizione fisica | 1 online resource (XI, 342 p. 44 illus., 41 illus. in color.) |
| Disciplina | 571.2 |
| Soggetto topico |
Plant physiology
Plant breeding Agriculture Plant Physiology Plant Breeding/Biotechnology Millorament selectiu de plantes Biotecnologia vegetal |
| Soggetto genere / forma | Llibres electrònics |
| ISBN | 3-030-27423-3 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | 1.Osmoprotectant-related genes in plants under abiotic stress: expression dynamics, in silico genome mapping, and biotechnology.-2.Proline metabolism and its functions in development and stress tolerance.-3. Regulation of proline accumulation and its molecular and physiological functions in stress defence -- 4. Exogenous proline-mediated abiotic stress tolerance in plants: possible mechanisms 5.-Biosynthesis and degradation of glycine betaine and its potential to control plant growth and development -- 6. Exogenous glycinebetaine-mediated modulation of abiotic stress tolerance in plants: possible mechanisms -- 7. Roles of endogenous glycinebetaine in plant abiotic stress responses -- 8.Biosynthesis and degradation of trehalose, and its potential to control -- 9. Proline, glycinebetaine and trehalose uptake and inter-organ transport in plants under stress -- 10. Transgenic plants overexpressing trehalose biosynthetic genes and abiotic stress tolerance in plants -- 11. The role of proline, glycine betaine and trehalose in stress responsive gene expression -- 12. Seed osmolyte priming and abiotic stress tolerance -- 13. Relationship between polyamines and osmoprotectants in the response to salinity of the legume-rhizobia symbiosis -- 14. Engineering polyamines metabolic pathways for abiotic stress tolerance in plants.-15. Fructan metabolism in plant growth and development and stress tolerance.-. |
| Record Nr. | UNINA-9910373921003321 |
| Cham : , : Springer International Publishing : , : Imprint : Springer, , 2019 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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Passivity-Based Control and Estimation in Networked Robotics / / by Takeshi Hatanaka, Nikhil Chopra, Masayuki Fujita, Mark W. Spong
| Passivity-Based Control and Estimation in Networked Robotics / / by Takeshi Hatanaka, Nikhil Chopra, Masayuki Fujita, Mark W. Spong |
| Autore | Hatanaka Takeshi |
| Edizione | [1st ed. 2015.] |
| Pubbl/distr/stampa | Cham : , : Springer International Publishing : , : Imprint : Springer, , 2015 |
| Descrizione fisica | 1 online resource (349 p.) |
| Disciplina | 629.892 |
| Collana | Communications and Control Engineering |
| Soggetto topico |
Control engineering
Robotics Automation System theory Control and Systems Theory Robotics and Automation Systems Theory, Control |
| ISBN | 3-319-15171-1 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | Scattering Variables Based Control of Bilateral Teleoperators -- Synchronization of Bilateral Teleoperators -- Passivity-Based Visual Feedback Estimation -- Passivity-Based Visual Feedback Control -- Output Synchronization for Network of Passive Systems -- Attitude Synchronization for Rigid Body Networks -- Pose Synchronization for Rigid Body Networks -- Cooperative Estimation for Visual Sensor Networks -- Appendices. |
| Record Nr. | UNINA-9910299841003321 |
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Hatanaka Takeshi
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| Cham : , : Springer International Publishing : , : Imprint : Springer, , 2015 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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Plant Nutrients and Abiotic Stress Tolerance [[electronic resource] /] / edited by Mirza Hasanuzzaman, Masayuki Fujita, Hirosuke Oku, Kamrun Nahar, Barbara Hawrylak-Nowak
| Plant Nutrients and Abiotic Stress Tolerance [[electronic resource] /] / edited by Mirza Hasanuzzaman, Masayuki Fujita, Hirosuke Oku, Kamrun Nahar, Barbara Hawrylak-Nowak |
| Edizione | [1st ed. 2018.] |
| Pubbl/distr/stampa | Singapore : , : Springer Singapore : , : Imprint : Springer, , 2018 |
| Descrizione fisica | 1 online resource (XXI, 590 p. 45 illus., 31 illus. in color.) |
| Disciplina | 581.1335 |
| Soggetto topico |
Plant physiology
Agriculture Soil science Soil conservation Plant breeding Plant Physiology Soil Science & Conservation Plant Breeding/Biotechnology |
| ISBN | 981-10-9044-0 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | Chapter 1. Biological functions, uptake and transport of essential nutrients in relation to plant growth -- Chapter 2. Role of Plant Nutrients in Plant Growth and Physiology -- Chapter 3. Foliar Application of Micronutrients in Mitigating Abiotic Stress in Crop Plants -- Chapter 4. Biofortification of Plant Nutrients: Present Scenario -- Chapter 5. Trace elements in abiotic stress tolerance -- Chapter 6. Biomolecular functions of micronutrients towards abiotic stress tolerance in plants -- Chapter 7. Phosphorus nutrition: plant growth in response to deficiency and excess -- Chapter 8. Role of potassium in governing photosynthetic processes and plant yield -- Chapter 9. Heavy Metal Tolerance in Two Algerian saltbushes: A Review on Plant Responses to Cadmium and Role of Calcium in Its Mitigation -- Chapter 10. Role of sulfur in plant abiotic stress tolerance: Molecular interactions and defense mechanisms -- Chapter 11. The role of silicon in plant tolerance on abiotic stress -- Chapter 12. Mechanisms of selenium-induced enhancement of abiotic stress tolerance in plants -- Chapter 13. Plant Nutrients and their Roles under Saline Soil Conditions -- Chapter 14. Ionic Basis of Salt Tolerance in Plants: Nutrient Homeostasis and Oxidative Stress Tolerance -- Chapter 15. Role of Micronutrients in Salt Stress Tolerance to Plants -- Chapter 16. Role of beneficial trace elements in salt stress tolerance of plants -- Chapter 17. Nutrient Homeostasis and Salt Stress Tolerance -- Chapter 18. Ion homeostasis and antioxidant defense towards salt tolerance in plants -- Chapter 19. Salinity Stress Alleviation by Organic and Inorganic Fertilization -- Chapter 20. Aspects of co-tolerance towards salt and heavy metal stresses in halophytic plant species -- Chapter 21. Role of mineral nutrients in plants growth under extreme temperatures -- Chapter 22. Molecular Approaches to Nutrient Uptake and Homeostasis in Plants under Abiotic Stress. |
| Record Nr. | UNINA-9910298440003321 |
| Singapore : , : Springer Singapore : , : Imprint : Springer, , 2018 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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