| Contributors |
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xi | |
| Preface |
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xv | |
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1 Alone NO Longer: Interactions of Nitric Oxide with Reactive Oxygen Species and Hydrogen Sulfide |
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1 | (14) |
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2 | (1) |
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2 Generation and Accumulation of NO |
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3 | (3) |
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3 Interactions between Reactive Mediators |
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6 | (1) |
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7 | (4) |
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11 | (4) |
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11 | (4) |
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2 S-Nitrosylation of Nuclear Proteins: New Pathways in Regulation of Gene Expression |
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15 | (26) |
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16 | (1) |
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2 Regulation of Gene Expression via Modification of Signaling Pathways |
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17 | (7) |
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3 Regulation of Gene Expression via Modification of Transcription Factors |
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24 | (2) |
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4 Regulation of Gene Expression via Modification of Chromatin Structure |
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26 | (6) |
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5 Conclusion 32 References |
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32 | (9) |
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3 Auxin and Nitric Oxide: A Counterbalanced Partnership Ensures the Redox Cue Control Required for Determining Root Growth Pattern |
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41 | (14) |
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42 | (2) |
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2 Indole Acetic Acid Induces Oxidative Stress and NO Production |
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44 | (1) |
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3 The Counterbalance between NO and ROS Operates Downstream Auxin and Is Critic for Determining Root Architecture |
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45 | (3) |
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4 Redox Regulation of Auxin Perception and Signaling |
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48 | (2) |
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5 Concluding Remarks and Perspectives |
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50 | (5) |
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50 | (5) |
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4 Control of Nitrogen Assimilation in Plants through S-nitrosothiols |
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55 | (24) |
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56 | (1) |
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2 Nitrate Uptake and Transport |
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57 | (3) |
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60 | (2) |
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4 Links between Nitrate Assimilation and Nitric Oxide Formation |
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62 | (3) |
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5 Redox Signaling by NO through Protein Modification |
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65 | (2) |
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6 The Role of NO in Nitrate Assimilation Pathways |
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67 | (4) |
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7 Conclusions and Future Remarks |
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71 | (8) |
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72 | (1) |
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72 | (7) |
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5 Functional Implications of S-Nitrosothiols under Nitrooxidative Stress Induced by Abiotic Conditions |
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79 | (18) |
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80 | (1) |
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81 | (5) |
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3 Role of GSNO as Cellular Signal |
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86 | (1) |
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4 Function of SNOs under Adverse Environmental Conditions |
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87 | (3) |
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5 Conclusions and Perspectives |
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90 | (7) |
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91 | (1) |
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91 | (6) |
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6 Costs and Benefits of Nitric Oxide Generation in Plants Exposed to Cadmium |
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97 | (26) |
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Magdalena Arasimowicz-Jelonek |
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Jolanta Floryszak-Wieczorek |
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98 | (1) |
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2 NO Costs in Cadmium Stress: From Sensing to Amplifying Cd-lnduced Pathology |
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99 | (5) |
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3 Benefits of NO Generation: From NO Priming to Cd Tolerance |
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104 | (6) |
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4 Is There Any Universality of NO Response During HM Stress? |
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110 | (4) |
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114 | (9) |
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115 | (8) |
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7 Role of NO-dependent Posttranslational Modifications in Switching Metabolic Pathways |
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123 | (22) |
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124 | (1) |
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2 NO in Plants: Production and Turnover |
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125 | (3) |
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3 NO-Dependent PTM Regulation in Plants |
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128 | (2) |
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4 Metabolic Pathways Affected by NO-dependent PTMs |
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130 | (6) |
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5 Conclusions and Future Research |
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136 | (9) |
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137 | (1) |
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138 | (7) |
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8 The Functional Role of Nitric Oxide in Plant Mitochondrial Metabolism |
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145 | (20) |
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146 | (1) |
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2 Nitric Oxide Generation in Mitochondria |
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147 | (2) |
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3 Scavenging of Nitric Oxide by Mitochondria |
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149 | (1) |
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4 Participation of Mitochondrial Generated Nitric Oxide in Cell Death |
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149 | (1) |
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5 AOX in Mitochondria and Relation to NO |
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150 | (1) |
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6 Nitrosylation and Nitration of Mitochondrial Proteins |
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150 | (5) |
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7 Genes Encoding Mitochondrial Proteins Are Regulated by NO |
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155 | (4) |
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8 Effect of NO on TCA Cycle via Aconitase |
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159 | (1) |
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9 Increasing Energy Yield in Mitochondria Mediated by Nitrite Reduction to Nitric Oxide |
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159 | (1) |
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160 | (5) |
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160 | (5) |
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9 Nitric Oxide and Reactive Oxygen Species in PCD Signaling |
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165 | (28) |
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166 | (3) |
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2 PCD Induction by NO and/or H2O2 |
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169 | (2) |
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3 NO and ROS Signaling during Senescence |
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171 | (2) |
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4 NO and ROS Interplay in Self-Incompatibility |
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173 | (2) |
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5 NO and ROS Crosstalk during Hypersensitive Response |
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175 | (3) |
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6 NO and ROS Involvement in PCD Induced by Abiotic Stress |
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178 | (6) |
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184 | (9) |
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184 | (9) |
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10 Nitric Oxide: Jack-of-All-Trades of the Nitrogen-Fixing Symbiosis? |
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193 | (26) |
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194 | (3) |
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2 NO in Plant and Bacteria |
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197 | (5) |
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3 NO Roles in Nitrogen-Fixing Symbiosis |
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202 | (9) |
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4 Conclusions and Future Directions |
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211 | (8) |
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213 | (1) |
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213 | (6) |
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11 Nitric Oxide Signaling during the Hypersensitive Disease Resistance Response |
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219 | (26) |
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220 | (1) |
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2 Origins of the NO Burst: Still Searching for an Answer |
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221 | (5) |
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3 NO Signal Transduction during the HR |
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226 | (3) |
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4 The Role of NO in the HR Cell Death |
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229 | (3) |
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5 NO and Immunity in Plants |
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232 | (2) |
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234 | (11) |
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235 | (1) |
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235 | (10) |
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12 Nitric Oxide-Mediated Chemical Signaling during Systemic Acquired Resistance |
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245 | (18) |
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1 Salicylic Acid Metabolism in Relation to SAR |
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246 | (3) |
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2 Free Radicals and Their Role in SAR |
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249 | (2) |
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3 Relationship among Free Radicals and Other SAR Signals and Lipids |
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251 | (3) |
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4 Fatty Acid Flux and SAR |
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254 | (9) |
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255 | (1) |
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255 | (8) |
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13 The Role of Nitric Oxide in Development and Pathogenesis of Biotrophic Phytopathogens - Downy and Powdery Mildews |
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263 | (22) |
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Zuzana Drabkova Trojanova |
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1 Nitric Oxide in Plant Responses to Pathogen Attack |
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264 | (2) |
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2 Sources of NO in Phytopathogens |
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266 | (2) |
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3 NO in the Pathogenesis of Fungal and Hemibiotrophic Phytopathogens |
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268 | (2) |
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4 NO in the Pathogenesis of Downy Mildews |
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270 | (4) |
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5 NO in the Pathogenesis of Powdery Mildews |
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274 | (3) |
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277 | (8) |
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277 | (1) |
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278 | (1) |
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278 | (7) |
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14 NO and Ca2+: Critical Components of Cytosolic Signaling Systems Involved in Stomatal Immune Responses |
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285 | (40) |
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286 | (1) |
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2 NO and Ca2+ Involve in Plant Innate Immunity |
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287 | (5) |
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3 NO and Ca2+ Signaling in Stomatal Innate Immunity |
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292 | (18) |
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4 Concluding Perspectives |
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310 | (15) |
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312 | (13) |
| Subject Index |
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325 | (16) |
| Author Index |
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341 | |
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