Mechanism of plant hormone signaling under stress: Volume 1
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Hoboken, NJ
Wiley Blackwell
[2017]
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| Beschreibung: | xxvii, 473 Seiten Illustrationen, Diagramme |
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| 245 | 1 | 0 | |a Mechanism of plant hormone signaling under stress |n Volume 1 |c edited by Girdhar K. Pandey |
| 264 | 1 | |a Hoboken, NJ |b Wiley Blackwell |c [2017] | |
| 300 | |a xxvii, 473 Seiten |b Illustrationen, Diagramme | ||
| 336 | |b txt |2 rdacontent | ||
| 337 | |b n |2 rdamedia | ||
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| 700 | 1 | |a Pandey, Girdhar K. |d 1972- |0 (DE-588)1135994854 |4 edt | |
| 700 | 1 | |a Pandey, Girdhar K. |4 edt | |
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Datensatz im Suchindex
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| adam_text | Contents
About the Editor xv
List of Contributors xvii
Preface xxiii
Part I Action of Phytohormones in Stress 1
1 Auxin as a Mediator of Abiotic Stress Responses 3
Branka Salopek-Sondi, Iva Pavlovic, Ana Smolko, and Dunja Samec
1.1 Introduction 3
1.2 Auxin: A Short Overview of Appearance, Metabolism, Transport, and
Analytics 4
1.2.1 De Novo Synthesis 4
1.2.2 Reversible and Irreversible Conjugation Pathways 5
1.2.3 IBA to IAA Conversion 6
1.2.4 Degradation Pathways 6
1.2.5 Polar Auxin Transport 7
1.2.6 Analytical Methods in Auxin Identification and Quantification 7
1.3 How Auxin Homeostasis Shifts with Diverse Abiotic Stresses 9
1.3.1 How the Auxin Pool is Affected by Abiotic Stress? 9
1.3.2 Transcription of Auxin Metabolic Genes under Abiotic Stress 10
1.3.3 What Can We Learn from Functional Analysis Research? 11
1.4 How Does Auxin Signaling Respond to Abiotic Stress? 13
1.4.1 Brief Overview of Auxin Perception and Signaling 13
1.4.2 Auxin Signaling Attenuation under Stress Conditions: The Importance of
miRNA Driven Post-Transcriptional Regulation 14
1.5 Auxin and Redox State During Abiotic Stress IS
1.6 Auxin-Stress Hormones Crosstalk in Stress Conditions 18
1.6.1 Auxin-ABA Crosstalk 18
1.6.2 Auxin-JA Crosstalk 19
1.6.3 Auxin-Ethylene Crosstalk 20
1.6.4 Auxin-SA Crosstalk 20
1.7 Promiscuous Protein Players of Plant Adaptation: Biochemical and
Structural Views 21
vi ļ Contents
1.7.1 IAR3 Auxin Amidohydrolase 21
1.7.2 GH3 Auxin Conjugate Synthetases 23
1.8 Conclusion 24
Acknowledgment 24
References 25
2 Mechanism of Auxin Mediated Stress Signaling in Plants 37
LekshmyS, Krishna G.K., Jha S.K., and Sairam R.K.
2.1 Introduction 37
2.2 Auxin Biosynthesis, Homeostasis, and Signaling 37
2.3 Auxin Mediated Stress Responses in Model and Crop Plants 40
2.4 Regulation of Root System Architecture under Drought and Nutrient
Stresses 41
2.5 Conclusions and Future Perspectives 45
References 46
3 Integrating the Knowledge of Auxin Homeostasis with Stress
Tolerance in Plants 53
Shivani Saini, Isha Sharma, and Pratap Kumar Pati
3.1 Introduction 53
3.2 Auxin Biosynthesis and its Role in Plant Stress 53
3.3 Auxin Transport and its Role in Plant Stress 57
3.4 Auxin Signaling and its Role in Plant Stress 60
3.5 Auxin Conjugation and Degradation and its Role in Plant Stress 61
3.6 Conclusions 63
References 63
4 Cytokinin Signaling in Plant Response to Abiotic Stresses 71
Nguyen Binh Anh Thu, Xuan Lan Thi Hoang, Mai Thuy True, Saad Sulieman,
Nguyen Phuong Thao, and Lam-Son Phan Tran
4.1 Introduction 71
4.2 CK Metabolism 72
4.2.1 CK Components and Regulatory Functions 72
4.2.2 CK Metabolism, Perception, and Signal Transduction 75
4.2.2.1 CK Metabolism 75
4.2.2.2 CK Perception and Signal Transduction 77
4.3 The Components of the CK Signaling Pathway 77
4.3.1 The CK Receptor Histidine Kinases 77
4.3.2 Histidine Phosphotransfer Proteins 79
4.3.3 Response Regulators 80
4.4 CK Signaling in Plant Responses to the Abiotic Stresses 81
4.5 Genetic Engineering of CK Content for Improvement of Plant Tolerance to
Abiotic Stresses 82
4.6 Conclusions 88
Acknowledgments 88
References 88
Contents
vii
5 Crosstalk Between Gibberellins and Abiotic Stress Tolerance
Machinery in Plants 101
Ashutosh Sharon, Jeremy Dkhar, Sneh Lata Singla-Pareek, and Ashwani Pareek
5.1 Introduction 101
5.2 Gibberellins: Biosynthesis, Transport, and Signaling 102
5.3 GA Metabolism and Signaling During Abiotic Stress 106
5.3.1 Salinity Stress Induces GA2ox and GA20ox Gene Expression 106
5.3.2 Reduced G A Confers Tolerance to Drought Stress 111
5.3.3 Role of GA in Cold and Heat Stresses 112
5.4 Crosstalk between GA and Other Plant Hormones in Response to Abiotic
Stresses 114
5.4.1 Crosstalk between G As and Ethylene During Abiotic Stress 114
5.4.2 Crosstalk Between G As and Abscisic Acid During Abiotic Stress 115
5.4.3 Crosstalk Between G As and SA During Abiotic Stress 116
5.4.4 Crosstalk Between GAs and Jasmonic Acid During Abiotic Stress 116
5.5 Applications in Crop Improvement 117
5.5.1 Flower Development 117
5.5.2 Fruit Development 118
5.5.3 Brewing Industry 118
5.6 Conclusion 118
Acknowledgment 119
References 119
6 The Crosstalk of GA and JA: A Fine-Tuning of the Balance of Plant
Growth, Development, and Defense 127
Yuge Li andXingliang Hou
6.1 Introduction 127
6.2 GA Pathway in Plants 128
6.3 JA Pathway in Plants 129
6.4 GA Antagonizes JA-Mediated Defense 131
6.5 JA Inhibits GA-Mediated Growth 133
6.6 G A and JA Synergistically Mediate Plant Development 134
6.7 Conclusions 136
Acknowledgments 136
References 136
7 Jasmonate Signaling and Stress Management in Plants 143
Sirhindi Geetika, Mushtaq Ruqia, Sharma Poonam, Kaur Harpreet, and Ahmad Mir
Mudaser
7.1 Introduction 143
7.2 JA Biosynthesis and Metabolic Fate 144
7.3 JA Signaling Network 146
7.4 Physiological Role of JAs 151
7.4.1 JA in Seed Germination 151
7.4.2 JA in Root Growth 151
7.4.3 JA in Tuber Formation 152
7.4.4 JA in Trichome Development 152
Contents
7.4.5 JA in Flower and Seed Development 153
7.4.6 JA in Abscission and Senescence 153
7АП JA in Photosynthesis Regulation 154
7,4.8 JA in Secondary Metabolism 155
7.5 JA Regulated Stress Responses 156
7.5.1 JA in Antioxidant Management and Reactive Oxygen Species
Homeostasis 156
7.5.2 JA in Biotic Stress 157
7.5.3 JA in Abiotic Stresses 157
7.6 Conclusion 159
References 159
8 Mechanism of ABA Signaling in Response to Abiotic Stress in
Plants 173
Ankush AshokSoddhe, Kundan Kumar, and Padmanabh Dwivedi
8.1 Introduction 173
8.2 Signal Perception and ABA Receptors 175
8.3 Negative Regulators of ABA Signaling: Protein Phosphatase 2C (PP2C) 178
8.4 Positive Regulators of ABA Signaling: SnRK2 179
8.5 ABA Signaling Regulating Transcription Factor 181
8.5.1 Basic-Domain Leucine Zipper (bZIP) TF 181
8.5.2 AP2/ERF TF 182
8.5.3 NAC TF 183
8.5.4 WRKY TF 183
8.5.5 C2H2 ZF TF 184
8.5.6 MYB TF 185
8.5.7 bHLH TF 185
8.6 Crosstalk Between Various ABA Responsive Pathways in Abiotic
Stress 186
8.7 Summary and Future Prospects 187
Acknowledgments 188
Abbreviations 188
References 188
9 Abscisic Acid Signaling and Involvement of Mitogen Activated
Protein Kinases and Calcium-Dependent Protein Kinases During
Plant Abiotic Stress 197
Aryadeep Roychoudhury and Aditya Banerjee
9.1 Introduction 197
9.2 ABA Signaling in Plants 198
9.2.1 ABA as a Phytohormone 198
9.2.2 ABA Metabolism 199
9.2.3 ABA Transport 199
9.2.4 ABA Perception and Signal Transduction 201
9.2.4.1 ABA Receptors in Signal Transduction 202
9.2A2 PP2Cs as Negative Regulators of ABA Signaling 203
9.2.4.3 SnRK2 Acting as a Global Positive Regulator of ABA Signaling 205
9.3 The Signalosome and Signaling Responses Mediated by ABA: Structural
Alterations in ABA by PYR/PYL/RCAR 207
9.4 Structural Alterations During PP2C Inhibition by ABA 208
9.5 The abil-1 Mutation Mystery Solved 208
9.6 Basic Leucine Zipper (bZIP) TFs in ABA Signaling 209
9.7 Mitogen-Activated Protein Kinase (MAPK) Cascades and Regulation of
Downstream Signaling 210
9.7.1 Relevance and Crosstalk of MAPKs in Plant Abiotic Stresses 212
9.7.2 The MAPK Families of Arabidopsis and Rice 212
9.7.2.1 Arabidopsis 212
97.2.2 Rice 213
9.7.3 MAPK Cascades Regulating Abiotic Stress Signaling 215
9.7.3.1 Salt Stress 215
9.7.3.2 Drought Stress 215
9.7.3.3 Oxidative Stress 215
9.7.3.4 Ozone Stress 216
9.7.3.5 Heavy Metal Stress 216
9.7.3.6 Temperature Stress 216
9.7.3.7 AB A-Induced Activation of MAPKs 216
9.8 Calcium Dependent Protein Kinases (CDPKs) 219
9.8.1 CDPK Activities 221
9.8.1.1 Regulation of CDPK Activity 221
9.8.1.2 CDPK in ABA Signaling 221
9.8.2 Relevance and Crosstalk of CDPKs in Plant Abiotic Stresses 223
9.8.3 CDPKs as Potent Signaling Hubs 224
9.9 MAPK-CDPK Crosstalk 225
9.10 Conclusion and Future Perspectives 226
Acknowledgments 227
References 227
10 Abscisic Acid Activates Pathogenesis-Related Defense Gene
Signaling in Lentils 243
Rebecca Ford, David Tan, Niloofar Vaghefi, and Barkat Mustafa
10.1 Plant Host Defense Mechanisms 243
10.1.1 Host versus Non-Host Resistance 243
10.1.2 Preformed and Induced Defense Responses 244
10.1.3 Reactive Oxygen Species (ROS) During an Oxidative Burst 245
10.1.4 Hypersensitive Response (HR) 245
10.1.5 Systemic Acquired Resistance (SAR) 246
10.2 Phytoalexins and Pathogenesis-Related (PR) Proteins 247
10.3 The Role of Plant Hormones in Pathogen Defense 247
10.3.1 Salicylic Acid 247
10.3.2 Jasmonic Acid 248
10.3.3 Ethylene 249
10.3.4 Abscisic Acid 249
10.3.5 Conservation and Crosstalk Within Signaling Pathways 250
10.4 The Lentil Ascochyta lends Pathosystem 251
X
Contents
10.5 Key Defense-Related Genes Involved in Ascochyta lentis Defense 252
10.6 The Effect of Exogenous Hormone Treatment on PR4 and PR10
Transcription in Lentils 253
10.6.1 Bioassays and cDNA Production 255
10.6.2 PR Gene Amplification and Expression Profiling 255
10.6.3 Effects of ABA, ACC, MeJA, and SA on Lentil PR4 Gene Expression 256
10.6.4 Effects of ABA,ACC,MeJA, and SA on Lentil PR10 Gene Expression 256
10.7 Conclusions 259
References 261
11 Signaling and Modulation of Non-Coding RNAs in plants by Abscisic
Acid (ABA) 272
Raj Kumar Joshi, Swati Megha, Urmila Basu, and NatN.V. Kav
11.1 Introduction 271
11.2 Biogenesis of Non-Coding RNAs in Plants 273
11.3 Mode of Action of ncRNAs in Plants 274
11.3.1 Mechanism of Action in Small RNAs 274
11.3.2 Mechanism of Action of IncRNAs 275
11.4 ABA Signaling in Plants 276
11.4.1 ABA Biosynthesis, Transport, and Catabolism 276
11.4.2 ABA Signal Transduction 278
11.4.3 C/s-Acting Elements and Transcription Factors in ABA-Mediated Gene
Expression 278
11.4.4 ABA-Mediated Stomatal Closure During Pathogen Attack 280
11.5 Non-Coding RNAs and ABA Response 280
11.5.1 MiRNAs in ABA Signaling 280
11.5.2 Other ncRNAs in ABA Signaling 283
11.6 Conclusion and Future Prospects 285
References 286
12 Ethylene and Stress Mediated Signaling in Plants: A Molecular
Perspective 295
Priyanka Agarwai, Gitanjali Jiwani, Ashima Khurana, Pankaj Gupta, and Rahul Kumar
12.1 Introduction 295
12.2 Types of Stress 295
12.2.1 Temperature Stress 296
12.2.1.1 Cold Stress 296
12.2.1.2 Heat Stress 296
12.2.2 Water Stress 297
12.2.2.1 Drought Stress 297
12.2.2.2 Salinity stress 298
12.3 Overview of Stress Signaling 298
12.3.1 Perception of Stress 298
12.3.1.1 Perception at Plasma Membrane 298
12.3.1.2 Perception by Changed Ca2+ Concentration 299
12.3.2 Action of Different Secondary Messengers 299
12.3.2.1 Reactive Oxygen Species (ROS) 299
Contents
12.3.2.2 Lipid Messengers 300
12.3.3 Ca2+ as an Intermediate Signal Molecule 301
12.3.4 Role of MAPK in Stress Signaling 302
12.3.5 Role of Ethylene During Stress 302
12.3.5.1 Ethylene 302
12.3.5.2 Ethylene Biosynthesis 302
12.3.5.3 Ethylene Perception 303
12.3.5.4 Role of Ethylene in Fruit Ripening 303
12.3.6 Role of Ethylene in Abiotic Stress 304
12.3.6.1 Cold Stress 304
12.3.6.2 Heat Stress 306
12.3.6.3 Salinity Stress 307
12.3.6.4 Ethylene and Drought Stress 310
12.3.6.5 Ethylene and Flooding Tolerance 310
12.3.7 Role of Ethylene in Biotic Stress 310
12.3.7.1 Ethylene Signal Perception in Response to Biotic Stress in Plants 310
12.3.7.2 Mechanism of Action of Ethylene in Plant Pathogen Interaction 311
12.3.7.3 Crosstalk of Hormones in Plant Defense 312
12.3.7.4 Crosstalk of Ethylene with Other Hormones in Response to Biotic
Stress 313
12.3.8 Role of ABA in Stress 315
12.3.9 Role of Other Phytohormones in Stress 316
12.4 Conclusion 316
Acknowledgment 316
References 317
13 Regulatory Function of Ethylene in Plant Responses to Drought,
Cold, and Salt Stresses 327
Hoixio Pei, Honglin Wang, Lijuan Wang, Fangfang Zheng, and Chun֊Hai Dong
13.1 Functional Roles of Ethylene in Plant Drought Tolerance 328
13.2 Ethylene Signaling in Plant Cold Tolerance 330
13.3 Ethylene Signaling and Response to Salt Stress 333
13.4 Conclusion 336
References 337
14 Plant Nitric Oxide Signaling Under Environmental Stresses 345
loneSalgado, Halley Caixeta Oliveirat, and Marilia Gaspar
14.1 Introduction 345
14.2 Mechanisms of NO Action in Plants 346
14.3 The Control of NO Homeostasis in Plants 348
14.3.1 NO Synthesis in Plants 349
14.3.2 NO Degradation in Plants 350
14.3.3 Regulation of NO Homeostasis by S~Nitrosothiols Through the Nitrogen
Assimilation Pathway 350
14.4 NO and the Response to Abiotic Stresses 351
14.4.1 Drought 351
14.4.2 Hypoxia Stress 352
Contents
14.4.3 Salt Stress 354
14.4.4 Heavy Metals 355
14.4.5 Low Temperature Stress 356
14.5 Conclusions and Future Prospects 358
References 360
15 Cell Mechanisms of Nitric Oxide Signaling in Plants Under Abiotic
Stress Conditions 371
Yuliya A. Krasyienko, Alla I. Yemets, and Yaroslav B. Blume
15.1 Introduction 371
15.2 Duality of RNS: Key Secondary Messengers in Plant Cells versus Nitrosative
Stress Agents 373
15.3 Tyrosine Nitration as a Hallmark of Nitrosative Stress and Regulatory
Post-Translational Modification 376
15.4 NO and Environmental Abiotic Challenges 380
15.4.1 Mechanical Wounding and Programmed Cell Death Progression 380
15.4.2 Chilling, Cold/Heat Stress, and Acclimation 380
15.4.3 Light Overexposure and UV Irradiation 382
15.4.4 Air (Ozone) and Soil Pollution (Heavy Metals, Herbicides) 384
15.4.5 Osmotic Stresses: High Salinity, Drought, and Flooding 386
15.5 Conclusions and Future Perspectives 388
Acknowledgments 389
References 389
16 S-Nitrosylation in Abiotic Stress in Plants and Nitric Oxide
Interaction with Plant Hormones 399
Ankita Sehrawat and Renu Deswal
16.1 Introduction 399
16.2 S-Nitrosylation in Abiotic Stress 400
16.2.1 Salinity Stress 401
16.2.2 Cold Stress 406
16.2.3 Desiccation Stress 406
16.2.4 High Light Stress 406
16.2.5 Cadmium and 2,4-Dichlorophenoxy Acetic Acid (2,4-D) Stress 406
16.3 Nitric Oxide and Plant Hormone Interaction 407
16.4 Conclusions and Future Areas of Research 409
References 409
17 Salicylic Acid Signaling and its Role in Responses to Stresses in
Plants 413
PingzhiZhao, Gui-Hua Lu, and Yong-Hua Yang
17.1 Introduction 413
17.2 Salicylic Acid Biosynthesis and Metabolism in Plants 414
17.2.1 SA Biosynthesis 414
17.2.2 SA Metabolism 416
17.3 Salicylic Acid: A Central Molecule in Plant Responses to Stress 417
17.3.1 SA-Mediated Plant Resistance to Disease 417
Contents
xiii
17.3.2 SA-Mediated Abiotic Stress Tolerance 419
17.3.2.1 Drought Stress 419
17.3.2.2 Cold and Heat Stress 421
17.3.2.3 Salinity Stress 423
17.3.2.4 Heavy Metal Stress 424
17.3.2.5 Ozone Stress and UV Radiation 42S
17.3.3 Relationship Between Biotic and Abiotic Stress Factors 426
17.4 Salicylic Acid in Relation to Other Phytohormones in Response to Plant
Stress Status 427
17.5 Conclusion 429
References 429
18 Glucose and Brassinosteroid Signaling Network in Controlling Plant
Growth and Development Under Different Environmental
Conditions 443
Monjul Singh, Aditi Gupta, and Ashverya Laxmi
18.1 Introduction 443
18.2 Glucose Homeostasis and Signaling in Plants 444
18.3 Brassinosteroid Biosynthesis and Signaling 447
18.4 Role of Glc in Plant Adaptation to Changing Environmental Conditions 452
18.5 Role of BR in Plant Adaptation to Changing Environmental Conditions 454
18.6 GlC BR Crosstalk and its Adaptive Significance in Plant Development 458
18.7 Conclusion and Future Perspective 459
References 459
Index 471
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| title | Mechanism of plant hormone signaling under stress |
| title_auth | Mechanism of plant hormone signaling under stress |
| title_exact_search | Mechanism of plant hormone signaling under stress |
| title_full | Mechanism of plant hormone signaling under stress Volume 1 edited by Girdhar K. Pandey |
| title_fullStr | Mechanism of plant hormone signaling under stress Volume 1 edited by Girdhar K. Pandey |
| title_full_unstemmed | Mechanism of plant hormone signaling under stress Volume 1 edited by Girdhar K. Pandey |
| title_short | Mechanism of plant hormone signaling under stress |
| title_sort | mechanism of plant hormone signaling under stress |
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