Senescence and Aging in Plants
- 1st Edition - August 28, 1988
- Imprint: Academic Press
- Editor: L.D. Nooden
- Language: English
- Paperback ISBN:9 7 8 - 0 - 1 2 - 4 1 4 2 7 9 - 4
- eBook ISBN:9 7 8 - 0 - 3 2 3 - 1 4 5 9 5 - 4
Senescence and Aging in Plants reviews the state of knowledge in the processes involved in plant senescence and aging. The book begins by discussing the emergence of senescence as… Read more
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Request a sales quoteSenescence and Aging in Plants reviews the state of knowledge in the processes involved in plant senescence and aging. The book begins by discussing the emergence of senescence as a concept; experimental analysis of senescence; and patterns of senescence. It then examines membrane deterioration during senescence; photosynthesis in relation to leaf senescence; senescence of detached plant organs; changing patterns of nucleic acid and protein synthesis during senescence; and degradative and associated assimilatory aspects of nitrogen removal. This is followed by chapters on aspects of ethylene that may impinge upon its role in promoting senescence of higher plants; the role of cytokinins in plant senescence; the promoters and retardants of senescence; and the role of calcium in plant senescence. The concept of whole plant senescence is discussed, which can be subdivided into patterns, correlative controls, cessation of vegetative growth, declining assimilatory processes, assimilate partitioning, and hormonal controls. The final chapters cover the deterioration of cellular membranes during the plant aging process and seed aging.
Contributors
Foreword
Preface
1 The Phenomena of Senescence and Aging
I. Emergence of Senescence as a Concept
II. Concepts
A. Senescence versus Aging
B. The Basic Units of Senescence
C. Death and Death Processes
D. The Senescence Syndrome: An Outline
III. Experimental Analysis of Senescence
A. Why Study Senescence?
B. Measures of Senescence
C. Correlative Controls
D. Attached versus Detached Structures
E. Hormonal Controls
IV. Patterns of Senescence
A. Overview
B. Cellular Patterns
C. Tissues
D. Organs
E. Organisms
F. Relationship between Stress and Senescence
G. Nonsenescence Processes
References
2 The Molecular Basis for Membrane Deterioration during Senescence
I. Introduction
II. Senescence of Microsomal and Plasma Membranes
A. Increased Production of Free Radicals
B. Changes in the Molecular Organization of Lipid Bilayers
C. A Tentative Model for Senescence of Microsomal Membranes
III. Thylakoid Membrane Senescence
A. Free Radical Production
B. Loss of Thylakoid Membrane Integrity
IV. Mitochondrial Membranes
V. Modulation of Membrane Senescence
VI. Conclusions
References
3 Photosynthesis
I. Introduction
II. Senescence of Chloroplasts
A. Ultrastructural Changes in Chloroplasts during Senescence
B. Autonomous Degradation of Chloroplasts
III. Chlorophyll Degradation
IV. Changes in Lipids during Chloroplast Senescence
V. Changes in Stromal Enzymes during Leaf Senescence
VI. Changes in the Components of the Chloroplast Thylakoid Membranes during Foliar Senescence
VII. Chloroplast Protein Degradation
VIII. Leaf Conductance and CO2 Assimilation in Senescing Leaves
IX. Conclusions
References
4 Respiration in Senescing Plant Organs: Its Nature, Regulation, and Physiological Significance
I. Introduction
II. Patterns of Respiration in Detached Plant Organs
A. Fruit
B. Leaves
C. Flowers
III. Causes of the Climacteric Rise in Respiration
IV. Mode of Action of Ethylene on Plant Respiration
V. Regulation of Plant Respiration
VI. Glycolysis
VII. Pentose Pathway
VIII. Tricarboxylic Acid Cycle
IX. Electron Transport
X. Residual
XI. Cellular Organization
XII. Physiological Significance of the Climacteric Rise in Plant Senescence
XIII. Summary
References
5 Nucleic Acid and Protein Synthesis
I. Introduction
II. Nucleic Acid and Protein Contents
A. DNA
B. RNA
C. Protein
III. Nucleic Acid and Protein Synthesis
A. DNA Synthesis
B. RNA Synthesis
C. Protein Synthesis
IV. Senescence Mutants
References
6 The Interplay between Proteolysis and Amino Acid Metabolism during Senescence and Nitrogen Reallocation
I. Introduction
II. Qualitative and Quantitative Description of Preanthesis Nitrogen Source
III. Protein Degradation
A. Generalized Concepts of Proteolysis
B. Protein Turnover
C. Nature of Protein-Degrading Enzymes
D. Generalized Concepts for the Regulation of Protein Degradation
IV. Senescence, Proteolysis, and the Metabolism of Nitrogen: Some Case Histories
A. Root and Nodule Senescence
B. Leaf Senescence
V. Concluding Remarks
References
7 Water Economy of Fruits and Fruiting Plants: Case Studies of Grain Legumes
I. Introduction
II. Water Balances of Developing Fruit and Seeds and Their Relationships to the Import of Carbon and Nitrogen through the Xylem and Phloem
III. Diurnal Water Balance of Fruit and the Fruiting Plant
IV. Structural Features of the Fruit and Their Significance in Terms of Water Relationships
V. Tracer Studies of the Phloem and Xylem Exchanges of Water and Solutes between Fruit, Peduncle, and the Remainder of the Plant
VI. General Conclusions
References
8 Ethylene and Plant Senescence
I. Introduction
II. Biosynthesis of Ethylene
A. Precursors and Pathway
B. Enzyme Systems
III. Regulation of Ethylene Biosynthesis
A. Methionine Recycling
B. Linkage with Polyamine Biosynthesis
C. Conjugation of ACC
D. Membrance Association and Involvement of Membrane Function
E. Feedback Controls
F. IAA-Induced Ethylene Production
IV. Ethylene in Fruit Ripening, Senescence, and Leaf Abscission
A. Ethylene and Fruit Ripening
B. Symptoms of Leaf Senescence
C. Exogenous Ethylene and Leaf-Blade Senescence
D. Endogenous Ethylene and Leaf-Blade Senescence
E. Interactions between Ethylene and Other Plant Hormones in Leaf-Blade Senescence
F. Exogenous Ethylene and Changes in the Abscission Zone
G. Interactions between Auxin and Ethylene in Abscission
H. Endogenous Ethylene in Abscission
I. Interactions between Ethylene and Other Factors in Natural Abscission
V. Mechanisms of Ethylene Action
VI. Conclusions
References
9 Cytokinins and Senescence
I. Introduction
II. Cytokinin Biochemistry and Physiology
A. Cytokinin Structure
B. Sites of Cytokinin Production
C. Cytokinin Transport
D. Cytokinin Metabolism
III. Evidence to Implicate Cytokinins in the Regulation of Senescence
IV. Cytokinins and Organ or Organism Senescence
A. Leaves
B. Cotyledons
C. Flowers
D. Fruit and Seed Senescence
E. Whole Plant Senescence
V. Relationships between Cytokinins and Other Hormones
VI. Conclusions
References
10 Abscisic Acid, Auxin, and Other Regulators of Senescence
I. Introduction
II. Abscisic Acid and Senescence Processes
A. Influence of Exogenous Abscisic Acid
B. Correlation with Endogenous Abscisic Acid
C. Relationships between Abscisic Acid and Other Hormones
III. Other Promoters of Senescence
A. Fatty Acids
B. Serine
C. Jasmonic Acid and Related Compounds
D. Miscellaneous Promoters
E. Unidentified Promoters
F. Hypersensitive Response
IV. Auxin and Senescence Processes
A. Influence of Exogenous Auxin
B. Correlation with Endogenous Auxin
C. Relationship between Auxin and Other Hormones
V. Gibberellin and Senescence Processes
A. Influence of Exogenous Gibberellin
B. Correlation with Endogenous Gibberellin
C. Relationship between Gibberellin and Other Hormones
VI. Other Retardants of Senescence
VII. Summary
A. What Hormone Is in Control?
B. Hormone Combinations
C. Integrated Hormone Systems
D. New Hormones?
E. Conclusion
References
11 Calcium and Senescence
I. Introduction
II. Calcium and Hormone Interactions
III. Cytosolic and Apoplastic Roles of Calcium
A. Cell Walls and Membranes
B. Calcium and Calmodulin
C. Protein Phosphorylation
IV. Role of Inositol Phospholipids in Calcium Messenger System
V. Conclusion
References
12 Whole Plant Senescence
I. Introduction
II. Patterns of Whole Plant Senescence
III. Correlative Controls
A. Cells and Organs as Components of the Organism
B. Control Centers versus Targets
C. Behavior of the Senescence Signal
IV. Cessation of Vegetative Growth as a Component of Whole Plant Senescence
V. Decline in Assimilatory Processes
A. Changes in Assimilation in the Roots and Leaves
B. Metabolic Decline in Plants with Reproductive Structures Removed ("Desinked")
VI. Partitioning and Redistribution of Assimilates in Relation to Senescence
A. Nutrient Diversion and Redistribution
B. Shift in Photosynthate Partitioning during Reproductive Development
C. Competition between the Fruits and Leaves for Mineral Nutrients Assimilated by the Roots
D. Controls of Assimilate Movement
E. Nutrient Redistribution
F. Exhaustion Death: Real or Apparent?
VII. Hormonal Controls
A. Introduction
B. The Senescence Signal
C. The Root/Shoot (Leaf) Interaction
VIII. Senescence of Polycarpic Plants
A. Introduction
B. Clonal Growth
C. Causes of Decline in Polycarpic Plants
D. Do Polycarpic Plants Senesce?
IX. Conclusions
References
13 Deterioration of Membranes during Aging in Plants: Evidence for Free Radical Mediation
I. Introduction
II. Evidence for Membrane Deterioraton during Aging
A. Seed Aging
B. Desiccation Tolerance
C. Freezing
D. Ice-Encasement
III. Physical Properties of Microsomal Membranes
A. Phase Properties
B. Freeze Fracture Electron Microscopy
C. Membrane Microviscosity
IV. Lipid and Protein Composition of Microsomal Membranes
A. Membrane Lipids
B. Membrane Proteins
V. Free Fatty Acids and Lipid Phase Properties
VI. Free Radicals
A. Phospholipid De-esterification
B. Free Radical Scavenging Systems
C. Production of Free Radicals
VII. Summary
References
14 Seed Aging: The Genome and Its Expression
I. Introduction
II. Historical Perspective
A. A False Dawn: Old Seeds of Oenothora Contain More "Mutants" Than New Seeds (1901-1931)
B. Chromosone Aberrations and Gene Mutations, or the Events That Give Rise to Them, Are Induced during Seed Storage (1933-1936)
C. Accumulation of Chromosome Damage Is a Function of Time, Temperature, and Moisture Content (1933-1939)
D. Recognition of a Simple Relation between Loss of Seed Viability and the Induction of Chromosome Damage (1967-1985)
E. The Concept of Repair during Moist Seed Storage (1974-1985)
F. The Amount of Chromosome Damage Associated with a Given Loss of Viability Is Large at Low-Moisture Contents and Is Minimal at High-Moisture Contents (1985)
III. The Nature of the Damage to the Genome and Its Expression
A. The Classical and Exchange Theories of Chromosome Damage
B. Chromatid-Type and Chromosome-Type Aberration in Seeds: Is the Damage Initiated during Aging or Afterward during Germination?
C. Speculations Concerning DNA Lesions That Result from Seed Aging
D. The Fate of Damage to the Genome
E. Damage to the Cellular Systems That Express the Genome
IV. Conclusions
References
15 Postlude and Prospects
I. Senescence versus Exogenously Driven Degeneration
II. What Is Senescence?
A. Required Processes
B. Central versus Peripheral Processes in Senescence
C. The Role of the Chloroplast in Senescence
D. Senescence as Parallel or Loosely Coupled Processes
E. Is Senescence One Process or Several?
F. Future Analyses of Senescence
III. What Hormone Is in Control?
IV. Limits on Life
V. Conclusions and Closing
References
Note Added in Proof
Index
- Edition: 1
- Published: August 28, 1988
- No. of pages (eBook): 564
- Imprint: Academic Press
- Language: English
- Paperback ISBN: 9780124142794
- eBook ISBN: 9780323145954
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