ISBN-13: 9783642701030 / Angielski / Miękka / 2011 / 524 str.
ISBN-13: 9783642701030 / Angielski / Miękka / 2011 / 524 str.
I am honored by the editor's invitation to write a Preface for this volume. As a member of an older generation of plant physiologists, my lineage in plant respiration traces back to F. F. BLACKMAN through the privilege of having M. THOMAS and W. O. JAMES, two of his "students," as my mentors. How the subject has changed in 40 years In those dark ages B. 14C. most of the information available was hard-won from long-term experiments using the input-output approach. Respiratory changes in response to treatments were measured by laborious gas analysis or by titration of alkali from masses of Pettenkofer tubes; the Warburg respir ometer was just beginning to be used for plant studies by pioneers such as TURNER and ROBERTSON. Nevertheless the classical experiments of BLACKMAN with apples had led to important results on the relations between anaerobic and aerobic carbohydrate utilization and on the climacteric, and to the first explicit concept of respiratory control of respiration imposed by the" organiza tion resistance" of cell structure. THOMAS extended this approach in his investi gations of the Pasteur effect and the induction of aerobic fermentation by poi sons such as cyanide and high concentrations of CO, JAMES began a long 2 series of studies of the partial reactions of respiration in extracts from barley and YEMM'S detailed analysis of carbohydrate components in relation to respira tory changes added an important new dimension."
1 Preparation of Plant Mitochondria, Criteria for Assessement of Mitochondrial Integrity and Purity, Survival in Vitro.- 1 Introduction.- 2 General Considerations for the Isolation of Intact Mitochondria.- 3 Large-Scale Preparation of Washed Mitochondria.- 3.1 Reagents.- 3.2 Procedure for Potato Tuber Mitochondria.- 4 Assessment of Mitochondrial Integrity.- 4.1 Spectrophotometric Assay for Succinate: Cytochrome c Oxidoreductase.- 4.2 KCN-Sensitive-Ascorbate-Cytochrome c-Dependent O2 Uptake.- 5 Control of Mitochondrial Purity.- 6 Purification of Plant Mitochondria.- 6.1 Purification on Sucrose Gradients.- 6.2 Purification on Percoll Gradients.- 6.2.1 Purification of Mitochondria from Potato Tubers.- 6.2.2 Purification of Mitochondria from Pea Leaves.- 6.2.3 Properties of Percoll-Purified Mitochondria.- 7 Concluding Remarks.- References.- 2 Molecular Organization and Expression of the Mitochondrial Genome of Higher Plants.- 1 Introduction.- 2 Physicochemical Characterization.- 2.1 Buoyant Density and Melting Point.- 2.2 Direct Observation of mtDNA Molecules by Electron Microscopy.- 2.3 C0t Curves and Kinetic Complexity.- 2.4 Detection of Discrete Circular mtDNA Molecules by Gel Electrophoresis.- 3 Restriction Analysis and Molecular Cloning.- 3.1 Restriction Patterns.- 3.2 Molecular Cloning.- 3.3 Physical Map(s) of mtDNA.- 4 Identified Mitochondrial Genes.- 4.1 rRNA Genes.- 4.2 tRNA Genes.- 4.3 Protein Genes.- 5 Concluding Remarks.- References.- 3 Plant Mitochondrial Lipids: Structure, Function and Biosynthesis.- 1 Introduction to Lipid Structures.- 2 Composition of Mitochondrial Membranes.- 2.1 Content of Acyl and Other Lipids.- 2.2 Comparison with Other Plant Membranes.- 3 Metabolism.- 3.1 Sources of Precursors for Lipid Synthesis.- 3.2 Mitochondrial Phospholipid Synthesis.- 3.3 Degradative Enzymes.- 4 Functional Aspects of Lipids.- 4.1 Membrane Structure and function.- 4.2 Changes in Mitochondrial Lipids.- 5 Conclusion.- References.- 4 Plant Mitochondrial Cytochromes.- 1 Introduction.- 2 Cytochrome Estimation.- 3 Mitochondrial Cytochromes in Higher Plants.- 3.1 The c Cytochromes.- 3.1.1 Cytochrome c.- 3.1.2 Cytochrome c1.- 3.2 The b Cytochromes.- 3.2.1 The Various Cytochromes b.- 3.2.2 The Cytochrome b-c1 Complex.- 3.2.3 Cytochromes b of the External Mitochondrial Membrane.- 3.3 The a Cytochromes.- 4 Influence of the Membrane Potential on the Redox States of the Mitochondrial Cytochromes.- 5 Miscellany.- 6 Cytochromes in the Respiratory Chain of Higher Plant Mitochondria.- References.- 5 The Outer Membrane of Plant Mitochondria.- 1 Perspective.- 2 Isolation of Mitochondrial Membranes.- 3 Lipid Composition of the Mitochondrial Outer Membrane.- 3.1 Lipid Classes.- 3.2 Fatty Acid Composition: Temperature Modulation.- 3.3 Lipid Phase Transitions.- 4 Enzymes of the Mitochondrial Outer Membrane.- 4.1 The NADH: Cytochrome c Oxidoreductase System.- 4.1.1 Possible Functions of the Outer Membrane Redox Chain.- 5 Channel-Formers of the Outer Mitochondrial Membrane.- 5.1 Structural Evidence for the Existence of Pores.- 5.2 Trypsin-Insensitive Polypeptides of the Plant Membrane.- 5.3 The Pore-Forming Polypeptides.- 5.4 Structure and Function of the Channels.- 5.4.1 Model from X-ray Diffraction.- 5.4.2 Structure from Electron Microscopy.- 5.4.3 Mechanism of Ion Selectivity.- 5.5 Speculation on a Regulatory Role for Outer Membrane Channels.- References.- 6 Organization of the Respiratory Chain and Oxidative Phosphorylation.- 1 Introduction.- 2 Organization of Respiratory Components.- 2.1 The Basic Functional Units.- 2.1.1 Complex I, NADH Dehydrogenase.- 2.1.2 Complex II, Succinate Dehydrogenase.- 2.1.3 Complex III, the Cytochrome bc1 Complex.- 2.1.4 Complex IV, Cytochrome Oxidase.- 2.1.5 The Alternative Oxidase.- 2.1.6 The External NADH Dehydrogenase.- 3 Connection Between the Functional Units.- 3.1 The Sidedness of the Reactions of the Alternative Oxidase, Succinate Dehydrogenase and the External NADH Dehydrogenase.- 3.2 The Role of Ubiquinone as a Mobile Redox “Pool”.- 3.2.1 Mobility Between Components.- 3.2.2 The Role of Ubiquinone in Providing Mobility.- 3.2.3 The Relation of the Quinone Pool to Control of Electron Flow Through the Cytochrome and Alternative Oxidases.- 3.3 Some Instances Where Ideal Q-Pool Behaviour Is Not Observed.- 4 Oxidative Phosphorylation.- 4.1 Background.- 4.2 Proton Electrochemical Gradient.- 4.2.1 Steady-State Ion Distribution.- 4.2.2 Spectroscopic Probes.- 4.2.3 Ion-Specific Electrodes.- 4.2.4 Magnitude of ? p and its Response to the Metabolic State.- 4.3 Mechanism for Generating ? p.- 4.3.1 H+/ORatios.- 4.3.2 H+/Site Ratios.- 4.3.3 H+/ATP Ratios.- 4.4 Thermodynamic Competence of ? p.- 4.5 Is ?p an Obligate Intermediate?.- References.- 7 The Oxidation of NADH by Plant Mitochondria.- 1 Introduction.- 2 NADH Dehydrogenases Oxidizing Exogenous NADH.- 2.1 The Outer Membrane NADH Dehydrogenase.- 2.2 The Inner Membrane NADH Dehydrogenase.- 2.2.1 Location of the Dehydrogenase.- 2.2.2 Nature of the Redox Components and Relationship with the Respiratory Chain.- 2.2.3 Inhibitors of the External Dehydrogenase.- 2.2.4 Specificity of the External NADH Dehydrogenase for the Nicotin-amide Adenine Dinucleotide.- 2.2.5 Regulation of Electron Flux Through the External NADH Dehydrogenase.- 2.2.6 The Physiological Significance of Regulation of the NADH Dehydrogenase.- 3 NADH Dehydrogenases Oxidizing Endogenous NADH.- 3.1 Rotenone-Sensitive Oxidation of Endogenous NADH.- 3.1.1 Redox Components Associated with the Dehydrogenase.- 3.1.2 Regulation of Electron Flow Through the Rotenone-Sensitive Dehydrogenase.- 3.2 Rotenone-Resistant Oxidation of Endogenous NADH.- 3.2.1 Relationship to the Terminal Oxidases.- 3.2.2 Relationship to the NAD+-Linked Krebs Cycle Dehydrogenases.- References.- 8 The Cyanide-Resistant Pathway of Plant Mitochondria.- 1 Introduction.- 2 The Measure of Cyanide Resistance.- 3 The Dependence on Respiratory Substrates.- 4 The Inhibition of Electron Transport.- 4.1 Inhibitors of the Flavoprotein Pathway.- 4.2 Inhibitors of the Cytochrome Pathway.- 4.3 Inhibitors of the Alternative Pathway.- 4.4 Interactions Between Inhibitors.- 5 The Link with Energy Transduction.- 5.1 Oxidative Phosphorylation.- 5.2 Membrane Potential and Proton Gradient.- 6 The Structure of the Alternative Pathway.- 6.1 Branch Point of the Alternative Pathway.- 6.2 Other Components.- 7 The Functional Organization of the Alternative Pathway.- 7.1 Topographical Organization.- 7.2 Compartmentation.- 7.2.1 Ubiquinone.- 7.2.2 Pyridine Nucleotides.- 7.3 Organization of the Alternative Pathway.- 8 The Alternative Pathway Oxidase.- 8.1 Flavoprotein Hypothesis.- 8.2 Excess Oxidase Hypothesis.- 8.3 Cytochrome b7 Hypothesis.- 8.4 Nonheme Iron Protein Hypothesis.- 8.5 Ubiquinone (Q-Cycle) Hypothesis.- 8.6 Quinol Oxidase Hypothesis.- 8.7 Lipoxygenase Hypothesis.- 8.8 Free Radical Hypothesis.- 8.9 Conclusions.- 9 The Distribution of Electrons Between the Two Pathways.- 9.1 Some Definitions and Remarks.- 9.2 Distribution of Electrons Between Pathways.- 9.2.1 Bahr and Bonner’s Method.- 9.2.2 De Troostembergh and Nyns’s Method.- 9.2.3 ADP/O Ratio Method.- 9.3 Mechanism of Electron Distribution.- 10 The Biogenesis of the Alternative Pathway.- 11 The Significance of the Alternative Pathway.- 12 Conclusion.- References.- 9 Membrane Transport Systems of Plant Mitochondria.- 1 Introduction.- 2 Structural and Osmotic Properties.- 3 Techniques of Measuring Transport.- 4 Transport of Inorganic Ions and Acetate.- 4.1 Background.- 4.2 Mechanisms of Passive Transport.- 4.3 Energy-Linked Transport.- 4.3.1 Salt Efflux.- 4.3.2 Salt Influx.- 5 Transport of Organic Metabolites and Cofactors.- 5.1 General Characteristics.- 5.2 Monocarboxylate Transport.- 5.3 Dicarboxylate Transport.- 5.4 Tricarboxylate Transport.- 5.5 Amino Acid Transport.- 5.6 Nucleotide Transport.- 6 Conclusions.- References.- 10 The Tricarboxylic Acid Cycle in Plant Mitochondria: Its Operation and Regulation.- 1 Introduction.- 2 Control.- 2.1 Adenylate Enery.- 2.2 Substrate Supply.- 2.3 Enzyme Activity.- 2.3.1 Enzyme Turnover.- 2.3.2 Pyruvate Dehydrogenase.- 2.3.3 Citrate Synthase.- 2.3.4 Isocitrate Dehydrogenase.- 2.3.5 Oxoglutarate Dehydrogenase.- 2.3.6 Succinyl Coenzyme A Synthetase.- 2.3.7 Succinate Dehydrogenase.- 2.3.8 Fumarase.- 2.3.9 Malate Dehydrogenase and Malic Enzyme.- 3 Fatty Acid Oxidation.- 3.1 Glyoxysome — Mitochondria Interactions.- 4 Malate Oxidation: Malate Dehydrogenase or NAD-Malic Enzyme?.- 5 Glycine Oxidation.- 6 Physiological Control of the TCA Cycle.- 7 List of Enzymes.- References.- 11 Leaf Mitochondria (C3 + C4 + CAM).- 1 Introduction.- 2 Effects of Light on Dark Respiration.- 3 Preparation of Leaf Mitochondria.- 3.1 Introduction.- 3.2 Development of Preparation Procedures.- 3.2.1 C3 Plants.- 3.2.2 CAM Plants.- 3.2.3 C4 Plants.- 4 Properties of Isolated Leaf Mitochondria.- 4.1 Purity and Intactness.- 4.2 Composition.- 5 Special Functions of Leaf Mitochondria — Role in Photorespiration.- 5.1 Photorespiration.- 5.2 Transport of Photorespiratory Metabolites.- 5.3 Glycine Decarboxylase.- 5.4 Serine Hydroxymethyltransferase.- 5.5 Assay Methods for Glycine Decarboxylase.- 5.6 Inhibition of Glycine Metabolism.- 5.7 Reoxidation of NADH.- 5.8 Regulation of Glycine Oxidation.- 5.9 Ammonia Refixation.- 6 Special Functions of Leaf Mitochondria — Role Relative to Decarboxylations in the C4 Cycle.- 6.1 Introduction.- 6.2 PEP-Carboxykinase Types.- 6.3 NADP-Malic Enzyme Types.- 6.4 NAD-Malic Enzyme Types.- 6.4.1 NAD-Malic Enzyme — A Mitochondrial Enzyme.- 6.4.2 Properties of NAD-Malic Enzyme.- 6.4.3 Function in NAD-ME Type C4 Plants.- 6.4.4 Function in ME Type CAM Plants.- 6.5 Transport in Mitochondria Relative to C4 and CAM Photosynthesis.- 6.6 Abundance and Ultrastructure of Mitochondria Relative to C4 Photosynthesis.- References.- 12 Starch and Sucrose Degradation.- 1 Introduction.- 2 Properties of Starch and Sucrose.- 2.1 Starch.- 2.2 Sucrose.- 3 Degradation of Starch and Sucrose.- 4 Relation Between Carbohydrate Mobilization and Respiration in Various Plant Tissues.- 4.1 Tissues Having a High Respiratory Carbohydrate Consumption.- 4.1.1 Tissues Where Starch is Almost Completely Respired to CO2.- 4.1.2 Cell Culture and Callus.- 4.1.3 Root Differentiation.- 4.2 Tissues Where Sucrose is Metabolized but Diverted to an Increasing Extent into Storage Products.- 4.2.1 Development of Lipid-Storing Seeds.- 4.2.2 Starch-Storing Tubers and Seeds.- 4.2.3 Storage of Sugar in Root Tubers.- 4.3 Tissues in Which Starch is Being Mobilized Primarily for Conversion to Sucrose.- 4.4 Photosynthetic Tissues with a Rapid Alteration Between Synthesis and Mobilization of Carbohydrate.- 4.4.1 Photosynthetic Metabolism.- 4.4.2 Sucrose Degradation.- 4.4.3 Starch Degradation.- 4.4.4 Carbohydrate Mobilization in CAM Plants.- 5 General Features of the Control of Carbohydrate Respiration.- 5.1 Control of Mobilization.- 5.1.1 Coarse Control of Enzymes.- 5.1.2 Multiple Forms of Enzymes.- 5.1.3 Compartmentation of Starch.- 5.1.4 Compartmentation of Sucrose.- 5.1.5 Fine Control of Enzymes.- 5.1.5.1 Starch.- 5.1.5.2 Sucrose.- 5.2 Control of the Utilization of Hexose P.- 5.2.1 Coarse Control of Hexose Phosphate Metabolism.- 5.2.2 Hexose Phosphate Metabolism and Compartmentation.- 5.2.3 Fine Control of Hexose Phosphate Metabolism.- 5.2.3.1 Phosphofructokinase.- 5.2.3.2 Fructose 2,6-Bisphosphate.- 5.2.3.3 Pyrophosphate: Fructose 6-phosphate Phosphotransferase.- 5.2.3.4 Pyrophosphate.- 5.2.3.5 Nonrespiratory Use of Hexose Phosphate.- 5.2.4 A Possible Integration of Pathways.- References.- 13 The Organization of Glycolysis and the Oxidative Pentose Phosphate Pathway in Plants.- 1 Introduction.- 2 Reactions of Glycolysis.- 2.1 Enzymes of Glycolysis.- 2.2 Pyrophosphate: Fructose 6-Phosphate 1-Phosphotransferase.- 3 Reactions of the Oxidative Pentose Phosphate Pathway.- 3.1 Enzymes of the Pathway.- 3.2 The Nonoxidative Reactions of the Pathway.- 4 Location and Inter-relationship of Glycolysis and the Oxidative Pentose Phosphate Pathway.- 4.1 Carbohydrate Oxidation in the Cytosol.- 4.2 Carbohydrate Oxidation in Plastids.- 4.2.1 Chloroplasts.- 4.2.2 Plastids Involved in Massive Synthesis of Fat.- 4.2.3 Other Plastids.- References.- 14 Respiration in Intact Plants and Tissues: Its Regulation and Dependence on Environmental Factors, Metabolism and Invaded Organisms.- 1 Introduction.- 2 Respiration Associated with Growth, Maintenance and Ion Uptake.- 2.1 Is There a Justification for the Concept of Growth Respiration?.- 2.1.1 Definitions and Basic Assumptions.- 2.1.2 Experimental Approaches.- 2.1.3 Experimentally Derived Values for YG and YEG Compared with Theoretical Values.- 2.1.4 Some Experimentally Derived Values and Their Significance.- 2.1.5 Summarizing Remarks.- 2.2 Respiration as an Aspect of the C-Economy of a Plant.- 3 Cyanide-Resistant Respiration: Its Distribution and Physiological Significance.- 3.1 Cyanide-Resistant Respiration in Vivo: Some Methodological Aspects.- 3.1.1 Cyanide-Resistant Oxygen Uptake.- 3.1.2 Cyanide-Sensitive Oxygen Uptake.- 3.1.3 SHAM-Sensitive Oxygen Uptake.- 3.1.4 The Determination of the Activity of the Alternative Path.- 3.2 Cyanide-Resistant Respiration and Heat Production.- 3.3 Cyanide-Resistance and Ion Uptake: “Anion Respiration”.- 3.4 The Alternative Path, Fruit Ripening, Ethylene Production and the Synthesis of Stress Metabolites.- 3.5 Cyanide-Resistance as a Mechanism to Tolerate Cyanide in the Environment.- 3.6 The Alternative Path in Relation to Anaplerotic Functions of Mitochondria.- 3.7 The “Energy Overflow” Model.- 3.8 The Alternative Path and an Increased Demand for Metabolic Energy.- 4 Regulatory Aspects of Respiration in Vivo.- 4.1 The Regulation of the Activity of the Cytochrome and the Alternative Pathways.- 4.2 The Regulation of Glycolysis.- 4.3 Regulation by the Concentration or Supply of Respiratory Substrates.- 4.4 Toward a Model of the Regulation of Respiration by Substrates and Adenylates.- 5 Respiration and Its Relation to Other Aspects of Metabolism.- 5.1 Ion Uptake.- 5.2 The “Movement” of Plants.- 5.3 Flowering.- 6 Respiration and Its Dependence on Environmental Factors.- 6.1 Effects of Light.- 6.1.1 Leaf Respiration After a Period of Photosynthesis.- 6.1.2 Respiration as Affected by Light Intensity During Growth.- 6.1.3 Respiration as Affected by the Integrated Level of Radiation.- 6.1.4 Further Remarks on Effects of Light.- 6.2 Effects of Temperature.- 6.2.1 The Q10 of Respiration.- 6.2.2 Transient Effects of Temperature on Respiration.- 6.2.3 Effects of Chilling.- 6.2.4 Effects of Supra-Optimal Temperatures.- 6.2.5 Temperature as an Ecological Factor.- 6.3 Effects of Salinity and Water Stress.- 6.4 Mineral Nutrition.- 7 Respiration and Its Relation to Yield and the Plasticity of the Individual.- 7.1 The Negative Correlation Between Respiration and Yield or Growth Rate.- 7.2 Are There Penalties, Associated with Slow Respiration Lines?.- 8 Developmental Aspects.- 8.1 Germination.- 8.2 Root and Leaf Development.- 8.3 Senescence.- 8.4 Fruit Ripening.- 9 Host-Parasite and Symbiotic Associations.- 9.1 Host-Parasite Associations.- 9.2 Symbiotic Systems.- 10 Concluding Remarks.- References.- Author Index.
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