Kooperativer Bibliotheksverbund

UID:

Format: XII, 289 S.

ISBN: 978-1-4020-8434-8 , 1-4020-8434-X

Series Statement: Plant ecophysiology 7

Language: English

Subjects: Biology

Keywords: Pflanzen ; Phosphorstoffwechsel ; Autökologie ; Aufsatzsammlung ; Aufsatzsammlung ; Aufsatzsammlung ; Aufsatzsammlung

URL: http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016531681&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA

URL: http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016531681&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA

UID:

Format: XII, 292 p. , online resource.

Edition: 1st ed. 2008.

ISBN: 9781402084355

Series Statement: Plant Ecophysiology, 7

Content: Phosphorus (P) is an essential macronutrient for plant growth. It is as phosphate that plants take up P from the soil solution. Since little phosphate is available to plants in most soils, plants have evolved a range of mechanisms to acquire and use P efficiently - including the development of symbiotic relationships that help them access sources of phosphorus beyond the plant's own range. At the same time, in agricultural systems, applications of inorganic phosphate fertilizers aimed at overcoming phosphate limitation are unsustainable and can cause pollution. This latest volume in Springer's Plant Ecophysiology series takes an in-depth look at these diverse plant-phosphorus interactions in natural and agricultural environments, presenting a series of critical reviews on the current status of research. In particular, the book presents a wealth of information on the genetic and phenotypic variation in natural plant ecosystems adapted to low P availability, which could be of particular relevance to developing new crop varieties with enhanced abilities to grow under P-limiting conditions. The book provides a valuable reference material for graduates and research scientists working in the field of plant-phosphorus interactions, as well as for those working in plant breeding and sustainable agricultural development.

Note: Phosphorus in the global environment -- Carbon/nitrogen/phosphorus allometric relations across species -- Phosphorus and aquatic plants -- Phosphorus nutrition of terrestrial plants -- Root strategies for phosphorus acquisition -- Plants without arbuscular mycorrhizae -- Mycorrhizal symbioses -- The role of rhizosphere microorganisms in relation to P uptake by plants -- Soil and fertilizer phosphorus in relation to crop nutrition -- Diagnosing phosphorus deficiency in crop plants -- Potential and limitations to improving crops for enhanced phosphorus utilization -- Phosphorus and the future.

In: Springer Nature eBook

Additional Edition: Printed edition: ISBN 9789048178810

Additional Edition: Printed edition: ISBN 9789048119967

Additional Edition: Printed edition: ISBN 9781402084348

Language: English

DOI: 10.1007/978-1-4020-8435-5

URL: https://doi.org/10.1007/978-1-4020-8435-5

UID:

Format: Online-Ressource , v.: digital

Edition: Online-Ausg. Springer eBook Collection. Biomedical and Life Sciences

ISBN: 9781402084355

Series Statement: Plant Ecophysiology 7

Content: Phosphorus (P) is an essential macronutrient for plant growth. It is as phosphate that plants take up P from the soil solution. Since little phosphate is available to plants in most soils, plants have evolved a range of mechanisms to acquire and use P efficiently – including the development of symbiotic relationships that help them access sources of phosphorus beyond the plant’s own range. At the same time, in agricultural systems, applications of inorganic phosphate fertilizers aimed at overcoming phosphate limitation are unsustainable and can cause pollution. This latest volume in Springer’s Plant Ecophysiology series takes an in-depth look at these diverse plant-phosphorus interactions in natural and agricultural environments, presenting a series of critical reviews on the current status of research. In particular, the book presents a wealth of information on the genetic and phenotypic variation in natural plant ecosystems adapted to low P availability, which could be of particular relevance to developing new crop varieties with enhanced abilities to grow under P-limiting conditions. The book provides a valuable reference material for graduates and research scientists working in the field of plant-phosphorus interactions, as well as for those working in plant breeding and sustainable agricultural development.

Note: Description based upon print version of record , Phosphorus in the global environment; Carbon/nitrogen/phosphorus allometric relations across species; Phosphorus and aquatic plants; Phosphorus nutrition of terrestrial plants; Root strategies for phosphorus acquisition; Plants without arbuscular mycorrhizae; Mycorrhizal symbioses; The role of rhizosphere microorganisms in relation to P uptake by plants; Soil and fertilizer phosphorus in relation to crop nutrition; Diagnosing phosphorus deficiency in crop plants; Potential and limitations to improving crops for enhanced phosphorus utilization; Phosphorus and the future;

Additional Edition: ISBN 9781402084348

Language: English

Subjects: Agriculture, Forestry, Horticulture, Fishery, Domestic Science , Biology

Keywords: Phosphor ; Pflanzenphysiologie ; Autökologie ; Aufsatzsammlung

DOI: 10.1007/978-1-4020-8435-5

URL: Volltext

UID:

Format: 1 online resource (817 pages)

Edition: Fourth edition.

ISBN: 0-323-85352-8

Note: Front Cover -- Marschner's Mineral Nutrition of Plants -- Copyright Page -- Contents -- List of contributors -- About the editors -- Foreword -- I. Nutritional physiology -- 1 Introduction, definition, and classification of nutrients -- Summary -- 1.1 General -- 1.2 Essential elements for plant growth -- 1.3 Beneficial elements for plant growth -- 1.4 A new definition of a mineral plant nutrient -- 1.5 Biochemical properties and physiological functions of nutrient elements in plants -- 1.6 Variation in the angiosperm ionome -- References -- Further reading -- 2 Ion-uptake mechanisms of individual cells and roots: short-distance transport -- Summary -- 2.1 General -- 2.2 Pathway of solutes from the external solution into root cells -- 2.2.1 Influx to the apoplasm -- 2.2.2 Passage into the cytoplasm -- 2.3 Composition of biological membranes -- 2.4 Solute transport across membranes -- 2.4.1 Thermodynamics of solute transport -- 2.4.2 Energy demand for solute transport -- 2.4.3 The kinetics of solute transport in plant roots -- 2.5 Factors influencing ion uptake by roots -- 2.5.1 Influx to the apoplasm -- 2.5.2 Effects of pH -- 2.5.3 Metabolic activity -- 2.5.3.1 Oxygen -- 2.5.3.2 Carbohydrates -- 2.5.3.3 Temperature -- 2.5.4 Interactions among ions in the rhizosphere -- 2.5.4.1 Competition -- 2.5.4.2 Effects of extracellular calcium -- 2.5.4.3 Cation-anion relationships -- 2.5.5 External concentration -- 2.5.6 Plant nutritional status -- 2.5.7 Studying nutrition at constant tissue concentration -- 2.6 Uptake of ions and water along the root axis -- 2.7 Radial transport of ions and water across the root -- 2.8 Release of ions into the xylem -- 2.9 Factors governing ion release into the xylem and exudation rate -- References -- 3 Long-distance transport in the xylem and phloem* -- Summary -- 3.1 General -- 3.2 Xylem transport. , 3.2.1 Composition of the xylem sap -- 3.2.2 Xylem loading -- 3.2.2.1 Exchange adsorption in xylem vessels -- 3.2.2.2 Retrieval and release of nutrients by living cells -- 3.2.2.3 Xylem unloading in leaves -- 3.2.3 Effect of transpiration rate on solute transport in the xylem -- 3.2.3.1 Plant age -- 3.2.3.2 Time of day -- 3.2.3.3 External concentration -- 3.2.3.4 Type of element -- 3.2.4 Effect of transpiration rate on distribution of elements within the shoot -- 3.3 Phloem transport -- 3.3.1 Principles of phloem transport and phloem anatomy -- 3.3.2 Phloem loading and the composition of phloem sap -- 3.3.3 Mobility in the phloem -- 3.3.4 Transfer between the xylem and phloem -- 3.3.5 Phloem unloading -- 3.4 Relative importance of phloem and xylem for long-distance transport of nutrients -- 3.4.1 General -- 3.4.2 Nutrients with high phloem mobility -- 3.4.3 Nutrients with low phloem mobility -- 3.4.4 Re-translocation and cycling of nutrients -- 3.5 Remobilization of nutrients -- 3.5.1 General -- 3.5.2 Seed germination -- 3.5.3 Vegetative stage -- 3.5.4 Reproductive stage -- 3.5.5 Perennials -- References -- 4 Uptake and release of elements by leaves and other aerial plant parts* -- Summary -- 4.1 General -- 4.2 Uptake and release of gases and other volatile compounds through stomata -- 4.2.1 Volatile nitrogen compounds -- 4.2.2 Volatile sulfur compounds -- 4.3 Uptake of solutes -- 4.3.1 General -- 4.3.2 Structure of the cuticle -- 4.3.3 Nutrient uptake through the cuticle -- 4.3.4 Uptake through stomata -- 4.3.5 Role of external factors -- 4.3.5.1 Environmental effects on the barrier properties during ontogenesis -- 4.3.5.2 Humidity effects on solute concentration and leaf permeability -- 4.3.5.3 Active ingredients and adjuvants -- 4.4 Foliar application of nutrients -- 4.4.1 General -- 4.4.2 Practical importance of foliar application of nutrients. , 4.4.2.1 Low nutrient availability in soils -- 4.4.2.2 Dry topsoil -- 4.4.2.3 Decrease in root activity during the reproductive stage -- 4.4.2.4 Avoiding the occurrence of physiological disorders and improving quality of horticultural crops -- 4.4.2.5 Biofortification -- 4.4.3 Foliar fertilizers for pest and disease control -- 4.4.4 Foliar uptake and irrigation methods -- 4.5 Leaching of elements from leaves -- 4.6 Ecological importance of foliar uptake and leaching -- 4.6.1 Foliar leaching -- 4.6.2 Foliar water absorption -- References -- 5 Mineral nutrition, yield, and source-sink relationships* -- Summary -- 5.1 General -- 5.2 Relationships between nutrient supply and yield -- 5.3 Photosynthetic activity and related processes -- 5.3.1 Photosynthetic energy flow and photophosphorylation -- 5.3.2 Photoinhibition and photooxidation -- 5.3.3 Carbon dioxide assimilation and photorespiration -- 5.3.4 C4 pathway of photosynthesis and Crassulacean acid metabolism -- 5.3.5 Effect of leaf maturation on its sink-source transition -- 5.3.6 Leaf senescence -- 5.3.7 Feedback regulation of photosynthesis by sink demand for carbohydrates -- 5.3.8 Nutrition and photosynthesis -- 5.4 Photosynthetic area -- 5.4.1 Individual leaf area -- 5.4.2 Leaf area per plant -- 5.4.3 Canopy leaf area (leaf area index and leaf area duration) -- 5.5 Respiration and oxidative phosphorylation -- 5.6 Transport of assimilates in phloem and its regulation -- 5.6.1 Phloem loading of assimilates -- 5.6.2 Mechanism of phloem transport of assimilates -- 5.6.3 Phloem unloading -- 5.7 Sink formation -- 5.7.1 Shoot architecture for grain/seed yield formation -- 5.7.2 Flower initiation and development -- 5.7.3 Pollination and seed development -- 5.7.4 Formation of vegetative sink organs -- 5.8 Sink activity -- 5.9 Role of phytohormones in the regulation of the sink-source relationships. , 5.9.1 Structure, sites of biosynthesis, and main effects of phytohormones -- 5.9.2 Phytohormones, signal perception, and signal transduction -- 5.9.3 Effects of nutrition on the endogenous concentrations of phytohormones -- 5.9.4 Phytohormones and sink action -- 5.10 Source and sink limitations on yield -- References -- 6 Functions of macronutrients* -- Summary -- 6.1 Nitrogen -- 6.1.1 Nitrate transport in plants -- 6.1.1.1 Nitrate uptake by roots -- 6.1.1.2 Nitrate efflux from roots -- 6.1.1.3 Radial transport of nitrate across the root and loading into xylem -- 6.1.1.4 Nitrate transport within the cell -- 6.1.1.5 Nitrate transport within the shoot -- 6.1.2 Ammonium transport into and within plants -- 6.1.2.1 Ammonium uptake by roots -- 6.1.2.2 Ammonium in the shoot -- 6.1.3 Organic N uptake -- 6.1.3.1 Amino acid uptake -- 6.1.3.2 Urea uptake and metabolism -- 6.1.4 Nitrogen assimilation -- 6.1.4.1 Nitrate reduction -- 6.1.4.2 Ammonium assimilation -- 6.1.4.3 Low-molecular-weight organic N compounds -- 6.1.5 Nitrogen supply, plant growth, and composition -- 6.1.5.1 Synergy between ammonium and nitrate nutrition -- 6.1.5.2 Ammonium toxicity -- 6.1.5.3 Nitrogen deficiency -- 6.1.5.4 Changes in root system architecture in response to N supply -- 6.1.5.5 Storage proteins -- 6.1.6 Nitrogen-use efficiency -- 6.2 Sulfur -- 6.2.1 General -- 6.2.2 Sulfate uptake, reduction, and assimilation -- 6.2.3 Metabolic functions of S -- 6.2.4 Sulfur supply, plant growth, and plant composition -- 6.3 Phosphorus -- 6.3.1 General -- 6.3.2 Phosphorus as a structural element -- 6.3.3 Role in energy transfer -- 6.3.4 Compartmentation and regulatory role of inorganic phosphate -- 6.3.5 Phosphorus fractions and the role of phytate -- 6.3.6 Phosphorus supply, plant growth, and plant composition -- 6.4 Magnesium -- 6.4.1 General. , 6.4.2 Binding form, compartmentation, and homeostasis -- 6.4.3 Chlorophyll and protein synthesis -- 6.4.4 Enzyme activation, phosphorylation, and photosynthesis -- 6.4.5 Carbohydrate partitioning -- 6.4.6 Magnesium supply, plant growth, and composition -- 6.5 Calcium -- 6.5.1 General -- 6.5.2 Binding form and compartmentation -- 6.5.3 Cell wall stabilization -- 6.5.4 Cell extension and secretory processes -- 6.5.5 Membrane stabilization -- 6.5.6 Cation-anion balance and osmoregulation -- 6.5.7 Calcium as an intracellular second messenger -- 6.5.8 Calcium as a systemic signal -- 6.5.9 Calcium supply, plant growth, and plant composition -- 6.6 Potassium -- 6.6.1 General -- 6.6.2 Compartmentation and cellular concentrations -- 6.6.3 Enzyme activation -- 6.6.4 Protein synthesis -- 6.6.5 Photosynthesis -- 6.6.6 Osmoregulation -- 6.6.6.1 Cell extension -- 6.6.6.2 Stomatal movement -- 6.6.6.3 Photonastic and seismonastic movements -- 6.6.7 Phloem transport -- 6.6.8 Energy transfer -- 6.6.9 Cation-anion balance -- 6.6.10 Stress resistance -- 6.6.11 Potassium supply, plant growth, and plant composition -- References -- 7 Micronutrients -- Summary -- 7.1 Iron -- 7.1.1 General -- 7.1.2 Iron-containing constituents of redox systems -- 7.1.2.1 Heme proteins -- 7.1.2.2 Fe-S proteins -- 7.1.3 Other Fe-requiring enzymes -- 7.1.4 Chloroplast development and photosynthesis -- 7.1.5 Localization and binding state of Fe -- 7.1.6 Root responses to Fe deficiency -- 7.1.7 Iron deficiency and toxicity -- 7.2 Manganese -- 7.2.1 General -- 7.2.2 Mn-containing enzymes -- 7.2.3 The functional role of Mn in photosynthesis -- 7.2.3.1 Manganese at the active site of water oxidation in photosystem II -- 7.2.4 Manganese in superoxide dismutase -- 7.2.5 Manganese in oxalate oxidase -- 7.2.6 Other Mn-dependent enzymes -- 7.2.7 Proteins, carbohydrates, and lipids. , 7.2.8 Cell division and extension.

Additional Edition: Print version: Rengel, Zed Marschner's Mineral Nutrition of Plants San Diego : Elsevier Science & Technology,c2022 ISBN 9780128197738

Language: English

UID:

Format: 1 online resource (817 pages)

Edition: Fourth edition.

ISBN: 0-323-85352-8

Note: Front Cover -- Marschner's Mineral Nutrition of Plants -- Copyright Page -- Contents -- List of contributors -- About the editors -- Foreword -- I. Nutritional physiology -- 1 Introduction, definition, and classification of nutrients -- Summary -- 1.1 General -- 1.2 Essential elements for plant growth -- 1.3 Beneficial elements for plant growth -- 1.4 A new definition of a mineral plant nutrient -- 1.5 Biochemical properties and physiological functions of nutrient elements in plants -- 1.6 Variation in the angiosperm ionome -- References -- Further reading -- 2 Ion-uptake mechanisms of individual cells and roots: short-distance transport -- Summary -- 2.1 General -- 2.2 Pathway of solutes from the external solution into root cells -- 2.2.1 Influx to the apoplasm -- 2.2.2 Passage into the cytoplasm -- 2.3 Composition of biological membranes -- 2.4 Solute transport across membranes -- 2.4.1 Thermodynamics of solute transport -- 2.4.2 Energy demand for solute transport -- 2.4.3 The kinetics of solute transport in plant roots -- 2.5 Factors influencing ion uptake by roots -- 2.5.1 Influx to the apoplasm -- 2.5.2 Effects of pH -- 2.5.3 Metabolic activity -- 2.5.3.1 Oxygen -- 2.5.3.2 Carbohydrates -- 2.5.3.3 Temperature -- 2.5.4 Interactions among ions in the rhizosphere -- 2.5.4.1 Competition -- 2.5.4.2 Effects of extracellular calcium -- 2.5.4.3 Cation-anion relationships -- 2.5.5 External concentration -- 2.5.6 Plant nutritional status -- 2.5.7 Studying nutrition at constant tissue concentration -- 2.6 Uptake of ions and water along the root axis -- 2.7 Radial transport of ions and water across the root -- 2.8 Release of ions into the xylem -- 2.9 Factors governing ion release into the xylem and exudation rate -- References -- 3 Long-distance transport in the xylem and phloem* -- Summary -- 3.1 General -- 3.2 Xylem transport. , 3.2.1 Composition of the xylem sap -- 3.2.2 Xylem loading -- 3.2.2.1 Exchange adsorption in xylem vessels -- 3.2.2.2 Retrieval and release of nutrients by living cells -- 3.2.2.3 Xylem unloading in leaves -- 3.2.3 Effect of transpiration rate on solute transport in the xylem -- 3.2.3.1 Plant age -- 3.2.3.2 Time of day -- 3.2.3.3 External concentration -- 3.2.3.4 Type of element -- 3.2.4 Effect of transpiration rate on distribution of elements within the shoot -- 3.3 Phloem transport -- 3.3.1 Principles of phloem transport and phloem anatomy -- 3.3.2 Phloem loading and the composition of phloem sap -- 3.3.3 Mobility in the phloem -- 3.3.4 Transfer between the xylem and phloem -- 3.3.5 Phloem unloading -- 3.4 Relative importance of phloem and xylem for long-distance transport of nutrients -- 3.4.1 General -- 3.4.2 Nutrients with high phloem mobility -- 3.4.3 Nutrients with low phloem mobility -- 3.4.4 Re-translocation and cycling of nutrients -- 3.5 Remobilization of nutrients -- 3.5.1 General -- 3.5.2 Seed germination -- 3.5.3 Vegetative stage -- 3.5.4 Reproductive stage -- 3.5.5 Perennials -- References -- 4 Uptake and release of elements by leaves and other aerial plant parts* -- Summary -- 4.1 General -- 4.2 Uptake and release of gases and other volatile compounds through stomata -- 4.2.1 Volatile nitrogen compounds -- 4.2.2 Volatile sulfur compounds -- 4.3 Uptake of solutes -- 4.3.1 General -- 4.3.2 Structure of the cuticle -- 4.3.3 Nutrient uptake through the cuticle -- 4.3.4 Uptake through stomata -- 4.3.5 Role of external factors -- 4.3.5.1 Environmental effects on the barrier properties during ontogenesis -- 4.3.5.2 Humidity effects on solute concentration and leaf permeability -- 4.3.5.3 Active ingredients and adjuvants -- 4.4 Foliar application of nutrients -- 4.4.1 General -- 4.4.2 Practical importance of foliar application of nutrients. , 4.4.2.1 Low nutrient availability in soils -- 4.4.2.2 Dry topsoil -- 4.4.2.3 Decrease in root activity during the reproductive stage -- 4.4.2.4 Avoiding the occurrence of physiological disorders and improving quality of horticultural crops -- 4.4.2.5 Biofortification -- 4.4.3 Foliar fertilizers for pest and disease control -- 4.4.4 Foliar uptake and irrigation methods -- 4.5 Leaching of elements from leaves -- 4.6 Ecological importance of foliar uptake and leaching -- 4.6.1 Foliar leaching -- 4.6.2 Foliar water absorption -- References -- 5 Mineral nutrition, yield, and source-sink relationships* -- Summary -- 5.1 General -- 5.2 Relationships between nutrient supply and yield -- 5.3 Photosynthetic activity and related processes -- 5.3.1 Photosynthetic energy flow and photophosphorylation -- 5.3.2 Photoinhibition and photooxidation -- 5.3.3 Carbon dioxide assimilation and photorespiration -- 5.3.4 C4 pathway of photosynthesis and Crassulacean acid metabolism -- 5.3.5 Effect of leaf maturation on its sink-source transition -- 5.3.6 Leaf senescence -- 5.3.7 Feedback regulation of photosynthesis by sink demand for carbohydrates -- 5.3.8 Nutrition and photosynthesis -- 5.4 Photosynthetic area -- 5.4.1 Individual leaf area -- 5.4.2 Leaf area per plant -- 5.4.3 Canopy leaf area (leaf area index and leaf area duration) -- 5.5 Respiration and oxidative phosphorylation -- 5.6 Transport of assimilates in phloem and its regulation -- 5.6.1 Phloem loading of assimilates -- 5.6.2 Mechanism of phloem transport of assimilates -- 5.6.3 Phloem unloading -- 5.7 Sink formation -- 5.7.1 Shoot architecture for grain/seed yield formation -- 5.7.2 Flower initiation and development -- 5.7.3 Pollination and seed development -- 5.7.4 Formation of vegetative sink organs -- 5.8 Sink activity -- 5.9 Role of phytohormones in the regulation of the sink-source relationships. , 5.9.1 Structure, sites of biosynthesis, and main effects of phytohormones -- 5.9.2 Phytohormones, signal perception, and signal transduction -- 5.9.3 Effects of nutrition on the endogenous concentrations of phytohormones -- 5.9.4 Phytohormones and sink action -- 5.10 Source and sink limitations on yield -- References -- 6 Functions of macronutrients* -- Summary -- 6.1 Nitrogen -- 6.1.1 Nitrate transport in plants -- 6.1.1.1 Nitrate uptake by roots -- 6.1.1.2 Nitrate efflux from roots -- 6.1.1.3 Radial transport of nitrate across the root and loading into xylem -- 6.1.1.4 Nitrate transport within the cell -- 6.1.1.5 Nitrate transport within the shoot -- 6.1.2 Ammonium transport into and within plants -- 6.1.2.1 Ammonium uptake by roots -- 6.1.2.2 Ammonium in the shoot -- 6.1.3 Organic N uptake -- 6.1.3.1 Amino acid uptake -- 6.1.3.2 Urea uptake and metabolism -- 6.1.4 Nitrogen assimilation -- 6.1.4.1 Nitrate reduction -- 6.1.4.2 Ammonium assimilation -- 6.1.4.3 Low-molecular-weight organic N compounds -- 6.1.5 Nitrogen supply, plant growth, and composition -- 6.1.5.1 Synergy between ammonium and nitrate nutrition -- 6.1.5.2 Ammonium toxicity -- 6.1.5.3 Nitrogen deficiency -- 6.1.5.4 Changes in root system architecture in response to N supply -- 6.1.5.5 Storage proteins -- 6.1.6 Nitrogen-use efficiency -- 6.2 Sulfur -- 6.2.1 General -- 6.2.2 Sulfate uptake, reduction, and assimilation -- 6.2.3 Metabolic functions of S -- 6.2.4 Sulfur supply, plant growth, and plant composition -- 6.3 Phosphorus -- 6.3.1 General -- 6.3.2 Phosphorus as a structural element -- 6.3.3 Role in energy transfer -- 6.3.4 Compartmentation and regulatory role of inorganic phosphate -- 6.3.5 Phosphorus fractions and the role of phytate -- 6.3.6 Phosphorus supply, plant growth, and plant composition -- 6.4 Magnesium -- 6.4.1 General. , 6.4.2 Binding form, compartmentation, and homeostasis -- 6.4.3 Chlorophyll and protein synthesis -- 6.4.4 Enzyme activation, phosphorylation, and photosynthesis -- 6.4.5 Carbohydrate partitioning -- 6.4.6 Magnesium supply, plant growth, and composition -- 6.5 Calcium -- 6.5.1 General -- 6.5.2 Binding form and compartmentation -- 6.5.3 Cell wall stabilization -- 6.5.4 Cell extension and secretory processes -- 6.5.5 Membrane stabilization -- 6.5.6 Cation-anion balance and osmoregulation -- 6.5.7 Calcium as an intracellular second messenger -- 6.5.8 Calcium as a systemic signal -- 6.5.9 Calcium supply, plant growth, and plant composition -- 6.6 Potassium -- 6.6.1 General -- 6.6.2 Compartmentation and cellular concentrations -- 6.6.3 Enzyme activation -- 6.6.4 Protein synthesis -- 6.6.5 Photosynthesis -- 6.6.6 Osmoregulation -- 6.6.6.1 Cell extension -- 6.6.6.2 Stomatal movement -- 6.6.6.3 Photonastic and seismonastic movements -- 6.6.7 Phloem transport -- 6.6.8 Energy transfer -- 6.6.9 Cation-anion balance -- 6.6.10 Stress resistance -- 6.6.11 Potassium supply, plant growth, and plant composition -- References -- 7 Micronutrients -- Summary -- 7.1 Iron -- 7.1.1 General -- 7.1.2 Iron-containing constituents of redox systems -- 7.1.2.1 Heme proteins -- 7.1.2.2 Fe-S proteins -- 7.1.3 Other Fe-requiring enzymes -- 7.1.4 Chloroplast development and photosynthesis -- 7.1.5 Localization and binding state of Fe -- 7.1.6 Root responses to Fe deficiency -- 7.1.7 Iron deficiency and toxicity -- 7.2 Manganese -- 7.2.1 General -- 7.2.2 Mn-containing enzymes -- 7.2.3 The functional role of Mn in photosynthesis -- 7.2.3.1 Manganese at the active site of water oxidation in photosystem II -- 7.2.4 Manganese in superoxide dismutase -- 7.2.5 Manganese in oxalate oxidase -- 7.2.6 Other Mn-dependent enzymes -- 7.2.7 Proteins, carbohydrates, and lipids. , 7.2.8 Cell division and extension.

Additional Edition: Print version: Rengel, Zed Marschner's Mineral Nutrition of Plants San Diego : Elsevier Science & Technology,c2022 ISBN 9780128197738

Language: English

UID:

Format: 1 online resource (817 pages)

Edition: Fourth edition.

ISBN: 0-323-85352-8

Note: Front Cover -- Marschner's Mineral Nutrition of Plants -- Copyright Page -- Contents -- List of contributors -- About the editors -- Foreword -- I. Nutritional physiology -- 1 Introduction, definition, and classification of nutrients -- Summary -- 1.1 General -- 1.2 Essential elements for plant growth -- 1.3 Beneficial elements for plant growth -- 1.4 A new definition of a mineral plant nutrient -- 1.5 Biochemical properties and physiological functions of nutrient elements in plants -- 1.6 Variation in the angiosperm ionome -- References -- Further reading -- 2 Ion-uptake mechanisms of individual cells and roots: short-distance transport -- Summary -- 2.1 General -- 2.2 Pathway of solutes from the external solution into root cells -- 2.2.1 Influx to the apoplasm -- 2.2.2 Passage into the cytoplasm -- 2.3 Composition of biological membranes -- 2.4 Solute transport across membranes -- 2.4.1 Thermodynamics of solute transport -- 2.4.2 Energy demand for solute transport -- 2.4.3 The kinetics of solute transport in plant roots -- 2.5 Factors influencing ion uptake by roots -- 2.5.1 Influx to the apoplasm -- 2.5.2 Effects of pH -- 2.5.3 Metabolic activity -- 2.5.3.1 Oxygen -- 2.5.3.2 Carbohydrates -- 2.5.3.3 Temperature -- 2.5.4 Interactions among ions in the rhizosphere -- 2.5.4.1 Competition -- 2.5.4.2 Effects of extracellular calcium -- 2.5.4.3 Cation-anion relationships -- 2.5.5 External concentration -- 2.5.6 Plant nutritional status -- 2.5.7 Studying nutrition at constant tissue concentration -- 2.6 Uptake of ions and water along the root axis -- 2.7 Radial transport of ions and water across the root -- 2.8 Release of ions into the xylem -- 2.9 Factors governing ion release into the xylem and exudation rate -- References -- 3 Long-distance transport in the xylem and phloem* -- Summary -- 3.1 General -- 3.2 Xylem transport. , 3.2.1 Composition of the xylem sap -- 3.2.2 Xylem loading -- 3.2.2.1 Exchange adsorption in xylem vessels -- 3.2.2.2 Retrieval and release of nutrients by living cells -- 3.2.2.3 Xylem unloading in leaves -- 3.2.3 Effect of transpiration rate on solute transport in the xylem -- 3.2.3.1 Plant age -- 3.2.3.2 Time of day -- 3.2.3.3 External concentration -- 3.2.3.4 Type of element -- 3.2.4 Effect of transpiration rate on distribution of elements within the shoot -- 3.3 Phloem transport -- 3.3.1 Principles of phloem transport and phloem anatomy -- 3.3.2 Phloem loading and the composition of phloem sap -- 3.3.3 Mobility in the phloem -- 3.3.4 Transfer between the xylem and phloem -- 3.3.5 Phloem unloading -- 3.4 Relative importance of phloem and xylem for long-distance transport of nutrients -- 3.4.1 General -- 3.4.2 Nutrients with high phloem mobility -- 3.4.3 Nutrients with low phloem mobility -- 3.4.4 Re-translocation and cycling of nutrients -- 3.5 Remobilization of nutrients -- 3.5.1 General -- 3.5.2 Seed germination -- 3.5.3 Vegetative stage -- 3.5.4 Reproductive stage -- 3.5.5 Perennials -- References -- 4 Uptake and release of elements by leaves and other aerial plant parts* -- Summary -- 4.1 General -- 4.2 Uptake and release of gases and other volatile compounds through stomata -- 4.2.1 Volatile nitrogen compounds -- 4.2.2 Volatile sulfur compounds -- 4.3 Uptake of solutes -- 4.3.1 General -- 4.3.2 Structure of the cuticle -- 4.3.3 Nutrient uptake through the cuticle -- 4.3.4 Uptake through stomata -- 4.3.5 Role of external factors -- 4.3.5.1 Environmental effects on the barrier properties during ontogenesis -- 4.3.5.2 Humidity effects on solute concentration and leaf permeability -- 4.3.5.3 Active ingredients and adjuvants -- 4.4 Foliar application of nutrients -- 4.4.1 General -- 4.4.2 Practical importance of foliar application of nutrients. , 4.4.2.1 Low nutrient availability in soils -- 4.4.2.2 Dry topsoil -- 4.4.2.3 Decrease in root activity during the reproductive stage -- 4.4.2.4 Avoiding the occurrence of physiological disorders and improving quality of horticultural crops -- 4.4.2.5 Biofortification -- 4.4.3 Foliar fertilizers for pest and disease control -- 4.4.4 Foliar uptake and irrigation methods -- 4.5 Leaching of elements from leaves -- 4.6 Ecological importance of foliar uptake and leaching -- 4.6.1 Foliar leaching -- 4.6.2 Foliar water absorption -- References -- 5 Mineral nutrition, yield, and source-sink relationships* -- Summary -- 5.1 General -- 5.2 Relationships between nutrient supply and yield -- 5.3 Photosynthetic activity and related processes -- 5.3.1 Photosynthetic energy flow and photophosphorylation -- 5.3.2 Photoinhibition and photooxidation -- 5.3.3 Carbon dioxide assimilation and photorespiration -- 5.3.4 C4 pathway of photosynthesis and Crassulacean acid metabolism -- 5.3.5 Effect of leaf maturation on its sink-source transition -- 5.3.6 Leaf senescence -- 5.3.7 Feedback regulation of photosynthesis by sink demand for carbohydrates -- 5.3.8 Nutrition and photosynthesis -- 5.4 Photosynthetic area -- 5.4.1 Individual leaf area -- 5.4.2 Leaf area per plant -- 5.4.3 Canopy leaf area (leaf area index and leaf area duration) -- 5.5 Respiration and oxidative phosphorylation -- 5.6 Transport of assimilates in phloem and its regulation -- 5.6.1 Phloem loading of assimilates -- 5.6.2 Mechanism of phloem transport of assimilates -- 5.6.3 Phloem unloading -- 5.7 Sink formation -- 5.7.1 Shoot architecture for grain/seed yield formation -- 5.7.2 Flower initiation and development -- 5.7.3 Pollination and seed development -- 5.7.4 Formation of vegetative sink organs -- 5.8 Sink activity -- 5.9 Role of phytohormones in the regulation of the sink-source relationships. , 5.9.1 Structure, sites of biosynthesis, and main effects of phytohormones -- 5.9.2 Phytohormones, signal perception, and signal transduction -- 5.9.3 Effects of nutrition on the endogenous concentrations of phytohormones -- 5.9.4 Phytohormones and sink action -- 5.10 Source and sink limitations on yield -- References -- 6 Functions of macronutrients* -- Summary -- 6.1 Nitrogen -- 6.1.1 Nitrate transport in plants -- 6.1.1.1 Nitrate uptake by roots -- 6.1.1.2 Nitrate efflux from roots -- 6.1.1.3 Radial transport of nitrate across the root and loading into xylem -- 6.1.1.4 Nitrate transport within the cell -- 6.1.1.5 Nitrate transport within the shoot -- 6.1.2 Ammonium transport into and within plants -- 6.1.2.1 Ammonium uptake by roots -- 6.1.2.2 Ammonium in the shoot -- 6.1.3 Organic N uptake -- 6.1.3.1 Amino acid uptake -- 6.1.3.2 Urea uptake and metabolism -- 6.1.4 Nitrogen assimilation -- 6.1.4.1 Nitrate reduction -- 6.1.4.2 Ammonium assimilation -- 6.1.4.3 Low-molecular-weight organic N compounds -- 6.1.5 Nitrogen supply, plant growth, and composition -- 6.1.5.1 Synergy between ammonium and nitrate nutrition -- 6.1.5.2 Ammonium toxicity -- 6.1.5.3 Nitrogen deficiency -- 6.1.5.4 Changes in root system architecture in response to N supply -- 6.1.5.5 Storage proteins -- 6.1.6 Nitrogen-use efficiency -- 6.2 Sulfur -- 6.2.1 General -- 6.2.2 Sulfate uptake, reduction, and assimilation -- 6.2.3 Metabolic functions of S -- 6.2.4 Sulfur supply, plant growth, and plant composition -- 6.3 Phosphorus -- 6.3.1 General -- 6.3.2 Phosphorus as a structural element -- 6.3.3 Role in energy transfer -- 6.3.4 Compartmentation and regulatory role of inorganic phosphate -- 6.3.5 Phosphorus fractions and the role of phytate -- 6.3.6 Phosphorus supply, plant growth, and plant composition -- 6.4 Magnesium -- 6.4.1 General. , 6.4.2 Binding form, compartmentation, and homeostasis -- 6.4.3 Chlorophyll and protein synthesis -- 6.4.4 Enzyme activation, phosphorylation, and photosynthesis -- 6.4.5 Carbohydrate partitioning -- 6.4.6 Magnesium supply, plant growth, and composition -- 6.5 Calcium -- 6.5.1 General -- 6.5.2 Binding form and compartmentation -- 6.5.3 Cell wall stabilization -- 6.5.4 Cell extension and secretory processes -- 6.5.5 Membrane stabilization -- 6.5.6 Cation-anion balance and osmoregulation -- 6.5.7 Calcium as an intracellular second messenger -- 6.5.8 Calcium as a systemic signal -- 6.5.9 Calcium supply, plant growth, and plant composition -- 6.6 Potassium -- 6.6.1 General -- 6.6.2 Compartmentation and cellular concentrations -- 6.6.3 Enzyme activation -- 6.6.4 Protein synthesis -- 6.6.5 Photosynthesis -- 6.6.6 Osmoregulation -- 6.6.6.1 Cell extension -- 6.6.6.2 Stomatal movement -- 6.6.6.3 Photonastic and seismonastic movements -- 6.6.7 Phloem transport -- 6.6.8 Energy transfer -- 6.6.9 Cation-anion balance -- 6.6.10 Stress resistance -- 6.6.11 Potassium supply, plant growth, and plant composition -- References -- 7 Micronutrients -- Summary -- 7.1 Iron -- 7.1.1 General -- 7.1.2 Iron-containing constituents of redox systems -- 7.1.2.1 Heme proteins -- 7.1.2.2 Fe-S proteins -- 7.1.3 Other Fe-requiring enzymes -- 7.1.4 Chloroplast development and photosynthesis -- 7.1.5 Localization and binding state of Fe -- 7.1.6 Root responses to Fe deficiency -- 7.1.7 Iron deficiency and toxicity -- 7.2 Manganese -- 7.2.1 General -- 7.2.2 Mn-containing enzymes -- 7.2.3 The functional role of Mn in photosynthesis -- 7.2.3.1 Manganese at the active site of water oxidation in photosystem II -- 7.2.4 Manganese in superoxide dismutase -- 7.2.5 Manganese in oxalate oxidase -- 7.2.6 Other Mn-dependent enzymes -- 7.2.7 Proteins, carbohydrates, and lipids. , 7.2.8 Cell division and extension.

Additional Edition: Print version: Rengel, Zed Marschner's Mineral Nutrition of Plants San Diego : Elsevier Science & Technology,c2022 ISBN 9780128197738

Language: English

UID:

Format: xix, 795 Seiten : , Illustrationen, Diagramme.

Edition: Fourth edition

ISBN: 978-0-12-819773-8

Note: Literaturangaben

Language: English

Subjects: Agriculture, Forestry, Horticulture, Fishery, Domestic Science , Biology

Keywords: Nutzpflanzen ; Pflanzenernährung ; Mineralstoff ; Mineralstoffwechsel ; Ernährungsphysiologie ; Nährstoffaufnahme ; Pflanzen ; Mineralstoffversorgung ; Pflanzen ; Mineralstoffwechsel ; Samenpflanzen ; Mineralstoffversorgung ; Samenpflanzen ; Mineralstoffwechsel

URL: Inhaltsverzeichnis

Author information: Marschner, Horst, 1929-1996