Reactive oxygen, nitrogen and sulfur species in plants : production, metabolism, signaling and defense mechanisms. v. 2 / edited by Mirza Hasanuzzaman ... [et al.]. -- Hoboken, NJ : Wiley-Blackwell, 2019. – (58.843/R281/v.2) |
Contents
About the Editors xi
List of Contributors xv
Preface
xxi
Section III
Reactive Sulfur Species Metabolism and Signaling 645
27
Hydrogen Sulfide in Guard Cell Signaling
647
27.1
Introduction 647
27.2
Hydrogen Sulfide 648
27.3
Conclusion and Perspectives 652
Acknowledgments 653
References
653
28
Hydrogen Sulfide: A New Gasotransmitter in Plant Defenses 657
28.1
Introduction 657
28.2
H2S Biosynthesis 657
28.3
The Physiological Functions of H2S
659
28.4
Drought and Salt Stress 659
28.5
Extreme Temperature Stress 660
28.6
Heavy Metal and Metalloid Stress
660
28.7
Pathogen Stress 661
28.8
Interactions Between H2S and Other Signal Molecules 661
28.9
H2S and Other Phytohormones 661
28.10
H2S and ROS 662
28.11
Cross-Talk Between H2S and Other Gasotransmitters 663
28.12
Conclusion and Prospective 663
References
664
29
Interplay Between Hydrogen Sulfide and Calcium Signaling in Plant
Abiotic Stress Response and Adaptation
669
29.1
Introduction 669
29.2
Hydrogen Sulfide Signaling 670
29.3 Calcium
Signaling 671
29.4
Interplay Between Hydrogen Sulfide and Calcium Signaling 672
29.5
Heat Stress and Heat Tolerance
673
29.6
Heavy Metal Stress and Adaptation
674
29.7
Drought Stress and Stomatal Movement
676
29.8
Conclusion and Perspective 679
References
680
30
Reactive Sulfur Species-Key Regulators of Abiotic Stress Tolerance in
Plants 685
30.1
Introduction 685
30.2
Sulfate Uptake, Transport and Assimilation 686
30.3
Physiological Functions of S Metabolites
687
30.4
Sulfur Metabolism: Regulation and Role in Stress Tolerance 688
30.5
Conclusion and Future Perspectives
699
Abbreviations 700
References
701
31
Reactive Sulfur Species: A New Player in Plant Physiology? 715
31.1
Introduction 715
31.2
Reactive Sulfur Species Generation and Its Interplay with ROS 716
31.3
Hydrogen Sulfide as Non-Radical Reducing RSS 718
31.4
Role for RSS in Plant Development: Allicin as RSS Affects Root
Growth 720
31.5
Reactive Sulfur Species: From Fertilization to Induction of the Plant's Resistance 721
31.6
Reactive Sulfur Species as Defense Molecules in Plants and Its Mode of
Action in Microbes 723
31.7
Conclusion and Outlook 724
Acknowledgment 724
Abbreviations 725
References
725
32
Role of Reactive Sulfur Species in the Oxidative Metabolism in
Plants 729
32.1
Introduction 729
32.2
Reactive Sulfur Species (RSS) 731
32.3
Sources/Production of Reactive Sulfur Species 732
32.4
Mechanism Involved in the Production of RSS 732
32.5
Role of Reactive Sulfur Species in Plant Metabolism 734
32.6
Conclusion 739
Abbreviations 739
References
740
33
Hydrogen Sulfide in Plant Abiotic Stress Tolerance: Progress and
Perspectives 743
33.1
Introduction 743
33.2
H2S in Plant Abiotic Stress Tolerance
748
33.3
Conclusions and Future Prospects
766
Acknowledgments 767
References
767
Section IV
Crosstalk Among Reactive Oxygen, Nitrogen and Sulfur Species 777
34
Reactive Oxygen Species, Reactive Nitrogen Species and Oxidative
Metabolism Under Waterlogging Stress 779
34.1
Introduction 779
34.2
Reactive Oxygen Species and Oxidative Stress 780
34.3
Site of ROS Production 782
34.4
ROS Metabolism and Oxidative Damage Under Waterlogging Stress 783
34.5
Antioxidative Metabolism Under Waterlogging Stress 785
34.6
Antioxidant Metabolites 791
34.7
Reactive Nitrogen Species (RNS) and Nitrosative Stress 793
34.8
RNS Metabolism Under Waterlogging Stress
795
34.9
Interaction of NO with Plant Hemoglobins
797
34.10
RNS and Antioxidant Metabolism
798
34.11
Aerenchyma Formation Under Waterlogging
798
34.12
Conclusions and Future Perspectives
799
References
801
35
Reactive Oxygen and Nitrogen Species in Stress-Induced Programmed Death
of Plant Cultured Cells 813
35.1
Introduction 813
35.2
Reactive Oxygen Species in PCD of Plant Cultured Cells 814
35.3
Reactive Nitrogen Species in PCD of Plant Cultured Cells 816
35.4
Conclusion and Future Perspectives
817
References
818
36
Finding a Place for NO in Everyday Plant Life 821
36.1 Introduction 821
36.2
Nitric Oxide Synthesis and Modes of Action in Higher Plants 822
36.3
NO Effects on Photosynthesis 824
36.4
NO and NO3- Signaling 826
36.5
The Influence of NO on Photoassimilate Partitioning and Sink-Source Relations 827
36.6
Role of NO in Plant Sensing of its C to N Balance and Switching between Primary
and Secondary Metabolism 829
36.7
Conclusion and Future Perspectives
832
References
833
37 H2O2,
NO and H2S: Tailoring in Suiting Plants against Abiotic Stresses 841
37.1
Introduction 841
37.2
Interplay Between Hydrogen Peroxide and Nitric Oxide 844
37.3
Interplay Between Hydrogen Peroxide and Hydrogen Sulfide 846
37.4
Interplay Between Nitric Oxide and Hydrogen Sulfide 847
37.5
Interplay Among Hydrogen Peroxide, Nitric Oxide, and
Hydrogen Sulfide 849
Acknowledgments 850
References
850
38
Cross Talk Among Reactive Oxygen, Nitrogen and Sulfur During Abiotic
Stress in Plants 857
38.1
Introduction 857
38.2
Cellular Generation of Free Radicals
858
38.3
Role of Free Radicals in Plant Defense Under Abiotic Stress 863
38.4
Crosstalk Among ROS, RNS and RSS Under Abiotic Stress 866
38.5
Conclusion and Future Prospects
866
References
867
39 Emerging
Technologies for Enhancing ROS/RNS Homeostasis
873
39.1
Introduction 873
39.2
ROS/RNS Homeostasis in Plants 874
39.3
Application of Nitric Oxide Donors for Induction of Abiotic Stress
39.4
Perspectives for Nitric Oxide Donors in Agriculture 894
39.5
The Ways for Improvement of NO Donor Application 899
39.6 Transgenic
Approaches and Genome Editing for Regulation of ROS/NOS Homeostasis 901
References
905
40
Compartmentalization of Reactive Oxygen Species and Nitric Oxide Production
in Plant Cells 923
40.1
Introduction 923
40.2
Subcellular Localization of ROS and NO Production in Plant Cells 926
40.3
Conclusions and Future Perspectives
936
References
936
Index
947