The growth, reproduction and geographical distribution of plants are profoundly influenced by their physiological ecology: the interaction with the surrounding physical, chemical, and biological environments. This renowned textbook is notable in emphasizing that the mechanisms underlying plant physiological ecology can be found at the levels of biochemistry, biophysics, molecular biology, and whole-plant physiology. At the same time, the integrative power of physiological ecology is well-suited to assess the costs, benefits, and consequences of modifying plants for human needs, and to evaluate the role of plants in ecosystems. This new edition of "Plant Physiological Ecology" features updated material, as well as full color images throughout. Boxed entries provide extended discussions of selected issues, and a glossary and numerous references to the primary and review literature are included.
Contents Foreword (by David T. Clarkson) About the authors Foreword to the first edition by David T. Clarkson) Acknowledgments Abbreviations 1. ASSUMPTIONS AND APPROACHES Introduction--History, Assumptions, and Approaches 1 What is Ecophysiology? 2 The Roots of Ecophysiology 3 Physiological Ecology and the Distribution of Organisms 4 Time Scale of Plant Responses to Environment 5 Conceptual and Experimental Approaches 6 New Directions in Ecophysiology 7 The Structure of the Book References 2. PHOTOSYNTHESIS, RESPIRATION, AND LONG-DISTANCE TRANSPORT 2A. PHOTOSYNTHESIS 1 Introduction 2 General Characteristics of the Photosynthetic Apparatus 2.1 The "Light" and "Dark" Reactions of Photosynthesis 2.1.1 Absorption of Photons 2.1.2 Fate of the Excited Chlorophyll 2.1.3 Membrane-bound Photosynthetic Electron Transport and Bioenergetics 2.1.4 Photosynthetic Carbon Reduction 2.1.5 Oxygenation and Photorespiration 2.2 Supply and Demand of CO2 in the Photosynthetic Process 2.2.1 The CO2-response Curve 2.2.2 Supply of CO2 - Stomatal and Boundary layer Conductances 2.2.3 The Internal Conductance 3 Response of Photosynthesis to Light 3.1 Characterization of the Light Climate under a Leaf Canopy 3.2 Physiological, Biochemical, and Anatomical Differences between Sun and Shade Leaves 3.2.1 The Light-response Curve of Sun and Shade Leaves 3.2.2 Anatomy and Ultrastructure of Sun and Shade Leaves 3.2.3 Biochemical Differences between Shade and Sun Leaves 3.2.4 The Light-response Curve of Sun and Shade Leaves Revisited 3.2.5 The Environmental signal for Shade Acclimation in Chloroplasts 3.3 Effects of Excess Irradiance 3.3.1 Photoinhibition - Protection by Carotenoids of the Xanthophyll Cycle 3.3.2 Chloroplast Movement in Response to Changes in Irradiance 3.4 Responses to Variable Irradiance 3.4.1 Photosynthetic Induction 3.4.2 Light Activation of Rubisco 3.4.3 Post-illumination CO2 Assimilation and Sunfleck Utilization Efficiency 3.4.4 Metabolite Pools in Sun and Shade Leaves 3.4.5 Net Effect of Sunflecks on Carbon Gain and Growth 4 Partitioning of the Products of Photosynthesis and Regulation by "feedback" 4.1 Partitioning within the Cell 4.2 Regulation of the Rate of Photosynthesis by feedback 4.3 Sugar-induced Repression of Genes Encoding for Calvin-cycle Enzymes 4.4 Ecological impacts Mediated by source-sink Interactions 5 Responses to Availability of Water 5.1 Regulation of Stomatal Opening 5.2 The A-Ci Curve as Affected by Water Stress 5.3 Carbon isotope Discrimination in Relation to Water-use Efficiency 5.4 Other sources of Variation in Carbon isotope ratios in C3 Plants 6 Effects of Nutrient Supply on Photosynthesis 6.1 The Photosynthesis-nitrogen Relationship 6.2 Interactions of Nitrogen, Light and Water 6.3 Photosynthesis, Nitrogen, and Leaf Life-span 7 Photosynthesis and Leaf Temperature: Effects and Adaptations 7.1 Effects of High Temperatures on Photosynthesis 7.2 Effects of Low Temperatures on Photosynthesis 8 Effects of Air Pollutants on Photosynthesis 9 C4 Plants 9.1 Introduction 9.2 Biochemical and Anatomical Aspects 9.3 Physiology of C4 Photosynthesis 9.4 Intercellular and Intracellular Transport of Metabolites of the C4 Pathway 9.5 Photosynthetic Nitrogen-use Efficiency, Water-use Efficiency and Tolerance of High Temperatures 9.6 C3-C4 Intermediates 9.7 Evolution and Distribution of C4 Species 9.8 Carbon isotope Composition of C4 Species 10 CAM Plants 10.1 Introduction 10.2 Physiological, Biochemical and Anatomical Aspects 10.3 Water-use Efficiency 10.4 Incomplete and facultative CAM Plants 10.5 Distribution and Evolution of CAM Species 10.6 Carbon isotope Composition of CAM Species 11 Specialized Mechanisms Associated with Photosynthetic Carbon Acquisition in aquatic Plants 11.1 Introduction 11.2 The CO2 Supply in Water 11.3 The Use of bicarbonate by aquatic Macrophytes 11.4 The Use of CO2 from the Sediment 11.5 Crassulacean Acid Metabolism (CAM) in Water Plants 11.6 Variation in Carbon isotope Composition betwe