How plants communicate with their biotic environment /

How Plants Communicate with Their Biotic Environment addresses how plants perceive the presence of organisms (other plants, microbes, insects and nematodes) living in their proximity, how they manage to be attractive when these organisms are friendly, and how they defend themselves from foes.

Detalles Bibliográficos
Clasificación:Libro Electrónico
Otros Autores: Becard, Guillaume (Editor )
Formato: Electrónico eBook
Idioma:Inglés
Publicado: [Place of publication not identified] : Academic Press is an imprint of Elsevier, 2017.
Colección:Advances in botanical research ; v. 82.
Temas:
Plant cellular signal transduction.
Plant communities.
Transduction du signal cellulaire chez les plantes.
SCIENCE > Life Sciences > Anatomy & Physiology.
Plant cellular signal transduction
Plant communities
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Front Cover; Advances in Botanical Research; ADVANCES IN BOTANICAL RESEARCH; Advances in Botanical ResearchHow plants communicate with their biotic environmentVolume EditorGuillaume BecardLaboratoire ... ; CONTENTS; CONTRIBUTORS; PREFACE; One
  • Plant-PlantCommunication; One
  • From the Lab Bench to the Forest: Ecology and Defence Mechanisms of Volatile-Mediated 'Talking Trees'; 1. INTRODUCTION; 2. PLANTS BIOSYNTHESIZE AND EMIT VOLATILE ORGANIC CHEMICALS IN RESPONSE TO HERBIVORY: HOW DO PLANT-PLANT SIGNALS EMERGE?; 3. LAB-BASED ADVANCES IN PLANT-PLANT COMMUNICATION
  • 4. THE EVOLUTION OF PLANT-PLANT SIGNALS: HAS PLANT-PLANT SIGNALLING SELECTED FOR EMISSION AND PERCEPTION OF PARTICULAR VOLATIL ... 5. THE ECOLOGICAL CONSEQUENCES OF PLANT-PLANT SIGNALS: DO PLANT-PLANT SIGNALS MATTER COMPARED TO OTHER TYPES OF DEFENCE?; REFERENCES; Two
  • Allelopathy and the Role of Allelochemicals in Plant Defence; 1. INTRODUCTION; 2. PLANT DEFENCE AND THE ROLE OF ALLELOCHEMICALS; 2.1 Allelochemical Localization and Release Into the Environment; 3. CLASSIFICATION OF SECONDARY METABOLITES; 3.1 Phenolic Compounds and Their Derivatives; 3.2 Terpenoids; 3.3 Alkaloids
  • 3.4 Hydroxamic Acids of Benzoxazinoids: An Agronomic Case Study4. ALLELOCHEMICAL MODE OF ACTION; 4.1 Membrane Permeability; 4.2 Water and Nutrient Uptake; 4.3 Respiration; 4.4 Photosynthesis; 4.5 Protein and Nucleic Acid Synthesis and Growth Regulation; 5. LOCALIZATION AND TRANSPORT OF ALLELOCHEMICALS IN DONOR PLANTS; 5.1 Root Exudation of Allelochemicals; 5.2 Diffusion; 5.3 Vesicle Transport; 5.4 Ion Channels; 6. FACTORS INFLUENCING THE RELEASE OF ALLELOCHEMICALS FROM THE PLANT; 7. ROLE(S) OF ALLELOCHEMICALS IN THE RHIZOSPHERE, IN NEIGHBOURING PLANTS AND OTHER ORGANISMS
  • 7.1 Tolerance to Allelochemicals8. METABOLIC PROFILING OF ALLELOCHEMICALS IN COMPLEX PLANT OR SOIL EXTRACTS OR MIXTURES; 9. CONCLUSIONS; REFERENCES; Three
  • Communication Between Host Plants and Parasitic Plants; 1. INTRODUCTION; 2. THE ORIGINAL LIFE CYCLE OF OBLIGATE ROOT PARASITIC PLANTS; 3. THE HOST-DEPENDENT SEED GERMINATION OF OBLIGATE ROOT PARASITIC PLANTS; 3.1 The Germination Stimulants; 3.2 The Key Components of the Strigolactone Signalling Pathway; 3.3 Towards a Rhizosphere Signalling Paradigm?; 4. THE HOST-DEPENDENT HAUSTORIUM DEVELOPMENT IN ROOT PARASITIC PLANTS
  • 4.1 Facultative Orobanchaceae4.2 Obligate Orobanchaceae; 4.3 Haustorium Inducing Factors or How the Host Triggers Haustorium Formation; 5. HOST-PARASITE COMMUNICATIONS DURING AND AFTER HAUSTORIUM FORMATION; 6. HOST RESPONSE TO PARASITIC PLANT (BROOMRAPE) INFESTATION; 7. CONCLUSIONS; REFERENCES; Four
  • Plant-Plant Communication Through Common Mycorrhizal Networks; 1. INTRODUCTION; 2. EVIDENCE OF INTERPLANT SIGNALLING VIA COMMON MYCORRHIZAL NETWORKS; 2.1 Background; 2.2 Experimental Challenges; 2.3 The Discovery of Common Mycorrhizal Networks-Based Signals; 2.4 Speed of Signal Transfer

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