Plant innate immunity signals and signaling systems : bioengineering and molecular manipulation for crop disease management /
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Author / Creator: | Vidhyasekaran, P. |
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Imprint: | Dordrecht : Springer, 2020. |
Description: | 1 online resource (276 p.). |
Language: | English |
Series: | Signaling and Communication in Plants Signaling and communication in plants. |
Subject: | |
Format: | E-Resource Book |
URL for this record: | http://pi.lib.uchicago.edu/1001/cat/bib/12605022 |
Table of Contents:
- Intro
- Contents
- 1 Introduction
- 1.1 Signals and Signaling Systems Involved in Activation of Plant Innate Immune System
- 1.2 Bioengineering Technologies to Activate Plant Immunity Signaling Systems for Management of Crop Diseases
- 1.3 Molecular Manipulation of Plant Immunity Signaling Systems Using Abiotic or Biotic Elicitors for Management of Crop Diseases
- References
- 2 Manipulation of Calcium Ion Influx-Mediated Immune Signaling Systems for Crop Disease Management
- 2.1 Ca2+ Signaling Components
- 2.2 Bioengineering G-Proteins for Plant Disease Management
- 2.3 Engineering Glutamate-Gated Ca2+ Channel for Plant Disease Management
- 2.4 Engineering H+-ATPase for Plant Disease Management
- 2.5 Molecular Manipulation of H+-ATPase Proton Pump by Laminarin for Crop Disease Management
- 2.6 Manipulation of H+-ATPase Using Chitosan Commercial Formulations
- 2.7 Engineering Annexins for Crop Disease Management
- 2.8 Bioengineering Calmodulin Genes to Promote Immune Responses for Plant Disease Management
- 2.9 Engineering CBP60g Calmodulin-Binding Proteins for Disease Management
- 2.10 Engineering Calcium-Dependent Protein Kinase Genes for Crop Disease Management
- 2.11 Manipulation of Ca2+-Dependent Signaling Pathway by Vitamin B1
- References
- 3 Manipulation of Reactive Oxygen Species, Redox and Nitric Oxide Signaling Systems to Activate Plant Innate Immunity for Crop Disease Management
- 3.1 Complexity of ROS-Redox-NO Signaling System
- 3.2 Manipulation of ROS Signaling System Using Benzothiadiazole (BTH) for Crop Disease Management
- 3.2.1 BTH Triggers Oxidative Burst and Accumulation of ROS Through Phospholipid Signaling
- 3.2.2 BTH Triggers Accumulation of ROS Through Action of Peroxidases and Superoxide Dismutases
- 3.2.3 BTH May Trigger Accumulation of ROS Through Suppression of ROS-Degrading Enzymes
- 3.2.4 Fine-Tuning of Accumulation of ROS by BTH
- 3.2.5 BTH Activates NPR1 by Inducing ROS-Mediated Redox Signaling
- 3.2.6 BTH Primes the Plants for Faster and Stronger Production of ROS
- 3.2.7 Manipulation of Peroxidases by BTH for Crop Disease Management
- 3.2.8 BTH Induces Several Host Plant Defense Responses Downstream of ROS Signaling
- 3.2.9 Management of Fungal Diseases in Crop Plants by Triggering Immune Responses Using BTH
- 3.2.10 Management of Oomycete Diseases of Crop Plants by Triggering Plant Immune Responses Using BTH
- 3.2.11 Management of Bacterial Diseases in Crop Plants by Triggering Plant Immune Responses Using BTH
- 3.2.12 Management of Virus Diseases in Crop Plants by Triggering Plant Immune Responses Using BTH
- 3.2.13 Management of Phytoplasma Diseases of Crop Plants by Triggering Plant Immune Responses Using BTH
- 3.2.14 Management of Parasitic Plants by Manipulation of ROS Signaling System Using BTH