09144nam 2200577 450 991050848330332120230518152528.03-030-78420-7(CKB)5600000000080723(MiAaPQ)EBC6797301(Au-PeEL)EBL6797301(PPN)258842679(EXLCZ)99560000000008072320220726d2021 uy 0engurcnu||||||||txtrdacontentcrdamediacrrdacarrierPlant growth and stress physiology /Dharmendra K. Gupta, José Manuel Palma, editorsCham, Switzerland :Springer,[2021]©20211 online resource (284 pages)Plant in Challenging Environments ;Volume 33-030-78419-3 Intro -- Preface -- Contents -- Chapter 1: Plant Stress, Acclimation, and Adaptation: A Review -- 1.1 Introduction -- 1.2 Stresses in Plants -- 1.3 Plant Responses Against Multiple Stressors to Develop Tolerance -- 1.4 Acclimation and Adaptation Against Multiple Stressors Through Different Signalling Pathways -- 1.4.1 Redox Signalling -- 1.4.2 MAP Kinase Pathway -- 1.4.3 Role of Phytohormones and Growth Regulators in Stress Signalling Pathway -- 1.5 Tolerance to Heavy Metals -- 1.5.1 Synthesis of Metal Chelators -- 1.5.2 Secretion of Organic Acids in Root Exudates -- 1.6 Tolerance to Heat Stress -- 1.7 Tolerance to Salt Stress -- 1.8 Plant Immune Response Against Biotic Stress -- 1.9 Antioxidant Defense System -- 1.9.1 Enzymatic Antioxidative System -- 1.9.2 Non-enzymatic Antioxidative System -- 1.10 Conclusion and Future Prospects -- References -- Chapter 2: Insights into Role of Invisible Partners in Plant Growth and Development -- 2.1 Introduction -- 2.2 Novel Insights in Plant-Microbiome Research -- 2.3 Influence of Endophytes on Plant Primary Growth and Secondary Metabolism -- 2.4 Effect of Endophytes in Imparting Stress Tolerance to Host Plants -- 2.5 Endophytes-Mediated Biotic Stress Response in Host Plants -- 2.6 Role of Endophytes in Improving Phytoremediation -- 2.7 Bio-Active Secondary Metabolites Produced by Endophytes -- 2.8 Concluding Remarks and Future Research Directions -- References -- Chapter 3: High Temperature Sensing Mechanisms and Their Downstream Pathways in Plants -- 3.1 Introduction -- 3.2 Sensing of Warm Temperature -- 3.3 Pathways that Function Downstream to Warm Temperature Sensing -- 3.4 Sensing of Heat Stress -- 3.5 Pathways that Function Downstream to Heat Stress Sensing -- 3.5.1 HSFs- or MBF1c-Dependent Pathways to Protect Plants Against Heat Stress -- 3.5.2 Signals Involving Ca2+, ROS and NO.3.5.3 Plant Hormone Signaling -- 3.5.4 Integration of Unfolded Protein Responses in Cytosol and Endoplasmic Reticulum (ER) -- 3.6 Conclusions -- References -- Chapter 4: From Beneficial Bacteria to Microbial Derived Elicitors: Biotecnological Applications to Improve Fruit Quality -- 4.1 Introduction -- 4.2 Plant Fitness. Growth and Mechanisms for Adaptation to Stress. Factors Limiting Growth -- 4.3 The Multifactor Solution: PGPR -- 4.4 Case Study: Blackberry -- 4.5 Conclusions -- References -- Chapter 5: Come Hell or High Water: Breeding the Profile of Eucalyptus Tolerance to Abiotic Stress Focusing Water Deficit -- 5.1 Introduction -- 5.2 Data Mining Challenge: The State of the Art of Research on Biomarkers for Water Deficit Tolerance in Eucalyptus -- 5.3 Brief on Phenotypic Biomarkers and Environmental Conditions -- 5.3.1 Anatomical -- 5.3.2 Morphological and Growth Measures -- 5.3.3 Nutritional -- 5.3.4 Physiological -- 5.4 Statistical Issues -- 5.4.1 Reliable Data and Reproducible Results -- 5.4.2 Repeatability, Reliability and Accuracy -- 5.4.3 Criteria for Selecting Biomarkers -- 5.4.4 Field, Greenhouse and Molecular Sources of Information -- 5.4.5 Experimental Design -- 5.4.6 Statistical Tools -- 5.5 Eucalyptus Interplay and Outcomes -- 5.5.1 Functional Homeostasis -- 5.6 Gaps and Future Research Outlook -- 5.7 Conclusions -- References -- Chapter 6: Organic Fertilization of Fruit Trees as an Alternative to Mineral Fertilizers: Effect on Plant Growth, Yield and Fruit Quality -- 6.1 Introduction -- 6.2 Organic Amendment -- 6.2.1 Animal Manure -- 6.2.2 Municipal Biosolids -- 6.2.3 Cover Crops -- 6.2.4 Agro-Industry Wastes -- 6.2.5 Compost -- 6.3 Effect of Organic Matter on Plants -- 6.3.1 Effect on Nutritional Status and Growth -- 6.3.2 Effect on Yield and Fruit Quality -- 6.4 Biofertilizers -- 6.5 Conclusions -- References.Chapter 7: Evaluation of Turbulence Stress on Submerged Macrophytes Growing in Lowland Streams Using H2O2 as an Indicator -- 7.1 Introduction -- 7.2 Dominant Stressors in the Natural Water -- 7.3 Effect of Temperature on ROS and Antioxidant Activities -- 7.4 Effects of Photosynthesis on the H2O2 and Antioxidant Activities -- 7.5 The Indicator of the Fractions of Stresses Associated with the Turbulence Stresses -- 7.6 Stress Patterns of the Changing Light Intensity -- 7.7 Effect of the Water Turbulence on the Structural Components of the Macrophyte Tissues -- 7.8 Biomass -- 7.9 Conclusion -- References -- Chapter 8: Opportunities of Revegetation and Bioenergy Production in Marginal Areas -- 8.1 Global Solid Waste Generation -- 8.2 Nonhazardous Waste Treatment -- 8.3 Landfills Restoration. Postclosure Use -- 8.4 Bioenergy as Strategy in Closed Landfill -- 8.5 Conclusion -- References -- Chapter 9: Biochar Behaviour and the Influence of Soil Microbial Community -- 9.1 Introduction -- 9.2 Soil-Biochar Interaction (Biochar Behaviour in Soil) -- 9.3 Biochar-Soil Microbiota Interaction -- 9.3.1 The Role of Feeding Types -- 9.3.2 Bacteria -- 9.3.3 Fungi -- 9.3.4 Other Microbiotas -- 9.3.5 Archaeal -- 9.3.6 Nematodes -- 9.3.7 Actinomycetes -- 9.3.8 Enzyme Activities -- 9.3.9 Factors Modulating Biochar-Microbiota Behaviour -- 9.3.10 Biochar Feedstock -- 9.3.11 Pyrolysis Temperature -- 9.3.12 Soil Type -- 9.3.13 Biochar Application Rate -- 9.3.14 Particle Size -- 9.3.15 Residence Time (Aging) -- 9.3.16 Presence of Organic Compounds -- 9.3.17 Land Use and Agricultural Management Practices -- 9.3.18 Implications for Soil Ecosystem -- 9.3.19 Waste Management -- 9.3.20 Immobilization and Sorption of Contaminants -- 9.3.21 Potential Source of Nutrients -- 9.3.22 Biogeochemical Cycling -- 9.3.23 Soil Biological Diversity and Activity -- 9.3.24 Food Quality.9.4 Conclusions and Future Research -- References -- Chapter 10: New Insights into the Functional Role of Nitric Oxide and Reactive Oxygen Species in Plant Response to Biotic and Abiotic Stress Conditions -- 10.1 Introduction -- 10.2 Nitric Oxide Signalling in Plant Response to Stress Conditions -- 10.2.1 NO Signalling Under Biotic Stress -- 10.3 NO Signalling under Abiotic Stress -- 10.4 Reactive Oxygen Species and Oxidative Stress in Plants under Stress Conditions -- 10.4.1 Modulation of ROS Levels during Biotic Stress -- 10.4.2 Modulation of ROS Levels during Abiotic Stress -- 10.5 New Insights the Interaction Between NO and ROS in Plant Response to Stress Conditions -- 10.6 Conclusions -- References -- Chapter 11: Selenium Transport, Accumulation and Toxicity in Plants -- 11.1 Introduction -- 11.2 Selenium Uptake and Transport -- 11.3 Selenate -- 11.4 Selenite -- 11.5 Organic Selenium Compounds -- 11.6 Selenium Distribution, Translocation, and Accumulation -- 11.7 Beneficial Effects of Selenium for Plants -- 11.8 Selenium Toxicity in Plants -- 11.9 Toxicity of Selenoproteins -- 11.10 ROS-Induced Selenium Toxicity -- 11.11 RNS-Induced Selenium Toxicity -- 11.12 Phytoremediation -- 11.13 Phytoextraction -- 11.14 Phytovolatilization -- 11.15 Conclusions and Future Perspectives -- References -- Chapter 12: Selenium in Algae: Bioaccumulation and Toxicity -- 12.1 Introduction -- 12.2 Se Metabolism in Algae -- 12.2.1 Se Accumulation and Transformation -- 12.2.2 Se Beneficial Role, Toxicity and Detoxification Mechanisms -- 12.2.3 Algae as Se Bioindicators and Accumulators, and Their Applications -- 12.3 Conclusions -- References.Plant in challenging environments ;Volume 3.Growth (Plants)PlantsEffect of stress onCreixement (Plantes)thubEfecte de l'estrès sobre les plantesthubFisiologia vegetalthubLlibres electrònicsthubGrowth (Plants)PlantsEffect of stress on.Creixement (Plantes)Efecte de l'estrès sobre les plantesFisiologia vegetal581.31Gupta Dharmendra Kumar(Phytoremediation researcher),Palma José ManuelMiAaPQMiAaPQMiAaPQBOOK9910508483303321Plant growth and stress physiology2902889UNINA