Plant Abiotic Stress (eBook, ePUB)
Redaktion: Jenks, Matthew A.; Hasegawa, Paul M.
Plant Abiotic Stress (eBook, ePUB)
Redaktion: Jenks, Matthew A.; Hasegawa, Paul M.
- Format: ePub
- Merkliste
- Auf die Merkliste
- Bewerten Bewerten
- Teilen
- Produkt teilen
- Produkterinnerung
- Produkterinnerung
Hier können Sie sich einloggen
Bitte loggen Sie sich zunächst in Ihr Kundenkonto ein oder registrieren Sie sich bei bücher.de, um das eBook-Abo tolino select nutzen zu können.
A fully revised review of the latest research in molecular basis of plant abiotic stress response and adaptation Abiotic stressors are non-living environmental stressors that can have a negative impact on a plants ability to grow and thrive in a given environment. Stressors can range from temperature stress (both extreme heat and extreme cold) water stress, aridity, salinity among others. This book explores the full gamut of plant abiotic stressors and plants molecular responses and adaptations to adverse environmental conditions. The new edition of Plant Abiotic Stress provides up-to-date…mehr
- Geräte: eReader
- mit Kopierschutz
- eBook Hilfe
- Größe: 3.88MB
Dieser Download kann aus rechtlichen Gründen nur mit Rechnungsadresse in A, B, BG, CY, CZ, D, DK, EW, E, FIN, F, GR, HR, H, IRL, I, LT, L, LR, M, NL, PL, P, R, S, SLO, SK ausgeliefert werden.
- Produktdetails
- Verlag: John Wiley & Sons
- Seitenzahl: 336
- Erscheinungstermin: 30. Oktober 2013
- Englisch
- ISBN-13: 9781118764329
- Artikelnr.: 39939171
- Verlag: John Wiley & Sons
- Seitenzahl: 336
- Erscheinungstermin: 30. Oktober 2013
- Englisch
- ISBN-13: 9781118764329
- Artikelnr.: 39939171
transcription factor 1 Kenong Xu, Abdelbagi M. Ismail, and Pamela Ronald
1.1 Introduction 1 1.2 I solation of the rice Sub1 locus 3 1.3 Sub1 rice in
farmers' fields 5 1.4 The Sub1 effect 7 1.5 The Sub1-mediated gene network
7 1.6 Conclusion 11 2 Drought tolerance mechanisms and their molecular
basis 15 Paul E. Verslues, Govinal Badiger Bhaskara, Ravi Kesari, and M.
Nagaraj Kumar 2.1 Introduction 15 2.1.1 The water potential concept 15
2.1.2 Escape, avoidance, and tolerance strategies of drought response 16
2.1.3 What is drought tolerance? 17 2.1.4 Responses to longer-term moderate
water limitation versus stress shock and short-term response 18 2.1.5
Natural variation and next generation sequencing 19 2.2 Some key drought
tolerance mechanisms 20 2.2.1 Osmoregulation/osmotic adjustment 20 2.2.2
Regulated changes in growth 22 2.2.3 Redox buffering and energy metabolism
24 2.2.4 Senescence and cell death 27 2.2.5 Metabolism 28 2.3 Emerging
drought tolerance regulatory mechanisms 28 2.3.1 Drought perception and
early signaling 29 2.3.2 Alternative splicing 31 2.3.3 Post-translational
modification: ubiquitination and sumoylation 35 2.3.4 Kinase/phosphatase
signaling 35 2.4 Conclusion 38 3 Stomatal regulation of plant water status
47 Yoshiyuki Murata and Izumi C. Mori 3.1 Stomatal transpiration and
cuticular transpiration 47 3.2 Abiotic stress 51 3.2.1 Drought 51 3.2.2
Light and heat 54 3.2.3 Carbon dioxide 56 3.2.4 Ozone 57 3.3 Abiotic stress
and biotic stress 59 3.3.1 Interaction between ABA signaling and MeJA
signaling 59 3.3.2 Interaction with other signaling 60 3.4 C4 plants and
crassulacean acid metabolism 61 3.5 Conclusion 63 4 Root-associated stress
response networks 69 Jennifer P.C. To, Philip N. Benfey, and Tedd D. Elich
4.1 Introduction 69 4.2 Root organization 71 4.2.1 Root developmental zones
71 4.2.2 Root tissue types 73 4.3 Systems analysis of root-associated
stress responses 76 4.4 Root-tissue to system-level changes in response to
stress 78 4.4.1 Nitrogen 78 4.4.2 Salinity 85 4.4.3 Root system
architecture in stress responses 92 4.5 Conclusion 94 5 Plant
low-temperature tolerance and its cellular mechanisms 109 Yukio Kawamura
and Matsuo Uemura 5.1 Introduction 109 5.2 Chilling injury 110 5.2.1 Cold
inactivation of vacuolar H+-ATPase 110 5.2.2 Lipid phase transition (Lalpha
to Lß) 112 5.2.3 Chill-induced cytoplasmic acidification 113 5.2.4
Light-dependent chilling injury 114 5.3 Freezing injury 115 5.3.1
Freeze-induced ultrastructures in the plasma membrane 117 5.3.2 Another
freeze-induced injury of the plasma membrane 118 5.4 Cold acclimation 118
5.4.1 Lipid composition of the plasma membrane during cold acclimation 119
5.4.2 Changes in plasma membrane proteins during cold acclimation 120 5.4.3
Compatible solute accumulation during cold acclimation 120 5.5 Freezing
tolerance 121 5.5.1 Membrane cryostability due to lipid composition 122
5.5.2 Membrane cryostability due to hydrophilic proteins 122 5.5.3
Compatible solutes and freezing tolerance 123 5.5.4 Membrane cryodynamics
and membrane resealing 124 5.5.5 Other membrane cryodynamics 124 5.6
Conclusion 126 6 Salinity tolerance 133 Joanne Tilbrook and Stuart Roy 6.1
Plant growth on saline soils 133 6.1.1 Effects of salt stress on plant
growth 135 6.1.2 Osmotic stress 136 6.1.3 Ionic stress 137 6.2 Tolerance
mechanisms 138 6.2.1 Osmotic tolerance 138 6.2.2 Ionic tolerance 139 6.2.3
Ion exclusion 139 6.2.4 Ion tissue tolerance 140 6.3 Identification of
variation in salinity tolerance 140 6.3.1 Variation in current crops 140
6.3.2 Variation in near wild relatives 141 6.3.3 Variation in model species
143 6.3.4 New phenomic approaches to identify variation in salinity
tolerance 144 6.4 Forward genetic approaches to identify salinity tolerant
loci and candidate genes 144 6.4.1 QTL mapping 144 6.4.2 Transcriptomics
148 6.4.3 Proteomics 149 6.4.4 Metabolomics 150 6.5 Known candidate genes
for salinity tolerance 151 6.5.1 The high-affinity potassium transporter
family 152 6.5.2 The salt overly sensitive pathway 153 6.5.3 Vacuolar
Na+/H+ antiporters and vacuolar pyrophosphatases 154 6.5.4 Osmoprotectants
155 6.5.5 Calcium signaling pathways 155 6.6 Prospects for generating
transgenic crops 156 6.6.1 Overexpression of genes involved with the
transport of ions 158 6.6.2 Manipulation of genes involved in signaling
pathways 159 6.6.3 Altering the expression of genes involved in compatible
solute synthesis 159 6.6.4 The need for cell-type- and temporal-specific
expression 159 6.7 Conclusion 161 7 Molecular and physiological mechanisms
of plant tolerance to toxic metals 179 Matthew J. Milner, Miguel Piñeros,
and Leon V. Kochian 7.1 Introduction 179 7.2 Plant Zn tolerance 181 7.2.1
Physiology of Zn tolerance 181 7.2.2 Molecular biology of Zn tolerance 185
7.2.3 Role of metal-binding ligands in Zn tolerance 188 7.3 Plant Cd
tolerance 190 7.4 Plant aluminum tolerance 190 7.4.1 Physiology of Al
tolerance 190 7.4.2 Molecular biology of Al tolerance 194 7.5 Conclusion
196 8 Epigenetic regulation of abiotic stress responses in plants 203
Viswanathan Chinnusamy, Monika Dalal, and Jian-Kang Zhu 8.1 Introduction
203 8.2 Epigenetic controls of gene expression 204 8.2.1 Establishment of
histone code 205 8.2.2 DNA cytosine methylation 205 8.3 E pigenetic
regulation of abiotic stress responses 210 8.3.1 Stress regulation of genes
for histone modification and RdDM 211 8.3.2 Gene regulation mediated by
stress-induced histone modifications 212 8.3.3 Gene regulation mediated by
stress-induced changes in dna methylation 218 8.3.4 Stress-induced
transposon regulation 219 8.4 Transgenerational inheritance and adaptive
value of epigenetic modifications 220 8.5 Conclusion 221 9 Genomics of
plant abiotic stress tolerance 231 Dong-ha Oh, Maheshi Dassanayake, Hyewon
Hong, Suja George, Seol Ki Paeng, Anna Kroporn ika, Ray A. Bressan, Sang
Yeol Lee, Dae-Jin Yun, and Hans J. Bohnert 9.1 Genomics in plant
research--an introduction 231 9.2 Plant genomes 2012--a transient account
236 9.3 Genomes, transcriptomes, and bioinformatics 237 9.4 Genomes that
inform about abiotic stress 240 9.5 Plants evolved for salinity tolerance
242 9.6 ARMS genomes--Thellungiella genome sequences 244 9.6.1
Lineage-specific gene duplications 244 9.6.2 Divergence of transcriptome
profiles and responses 247 9.6.3 Lineage-specific genes 249 9.7 A breeding
strategy for abiotic stress avoidance 249 9.8 Conclusion 250 10 QTL and
association mapping for plant abiotic stress tolerance: trait
characterization and introgression for crop improvement 257 DELPHINE FLEURY
and Peter Langridge 10.1 Introduction 257 10.2 Genetic mapping of abiotic
stress tolerance traits 260 10.2.1 Quantitative trait loci 260 10.2.2 QTL
for abiotic stress tolerance 262 10.3 Association mapping of abiotic stress
tolerance traits 263 10.3.1 Linkage disequilibrium and population structure
263 10.3.2 Association study of abiotic stress tolerance 264 10.4 Transfer
of QTL findings to breeding programs 265 10.5 Issues in genetic analysis of
abiotic stress tolerance 268 10.5.1 Phenotyping methods 268 10.5.2
Selection of germplasm for genetic analysis 270 10.5.3 Stability of QTL
across environments 272 10.6 Current directions of quantitative genetics
for abiotic stress tolerance 274 10.6.1 Physiological components of abiotic
stress tolerance QTL 274 10.6.2 Integration of physiological components
into abiotic stress tolerance QTL 275 10.6.3 Meta QTL 276 10.6.4 New
population designs for QTL mapping 276 10.7 Conclusion 279 Index 289 Color
plate section is located between pages 132 and 133
transcription factor 1 Kenong Xu, Abdelbagi M. Ismail, and Pamela Ronald
1.1 Introduction 1 1.2 I solation of the rice Sub1 locus 3 1.3 Sub1 rice in
farmers' fields 5 1.4 The Sub1 effect 7 1.5 The Sub1-mediated gene network
7 1.6 Conclusion 11 2 Drought tolerance mechanisms and their molecular
basis 15 Paul E. Verslues, Govinal Badiger Bhaskara, Ravi Kesari, and M.
Nagaraj Kumar 2.1 Introduction 15 2.1.1 The water potential concept 15
2.1.2 Escape, avoidance, and tolerance strategies of drought response 16
2.1.3 What is drought tolerance? 17 2.1.4 Responses to longer-term moderate
water limitation versus stress shock and short-term response 18 2.1.5
Natural variation and next generation sequencing 19 2.2 Some key drought
tolerance mechanisms 20 2.2.1 Osmoregulation/osmotic adjustment 20 2.2.2
Regulated changes in growth 22 2.2.3 Redox buffering and energy metabolism
24 2.2.4 Senescence and cell death 27 2.2.5 Metabolism 28 2.3 Emerging
drought tolerance regulatory mechanisms 28 2.3.1 Drought perception and
early signaling 29 2.3.2 Alternative splicing 31 2.3.3 Post-translational
modification: ubiquitination and sumoylation 35 2.3.4 Kinase/phosphatase
signaling 35 2.4 Conclusion 38 3 Stomatal regulation of plant water status
47 Yoshiyuki Murata and Izumi C. Mori 3.1 Stomatal transpiration and
cuticular transpiration 47 3.2 Abiotic stress 51 3.2.1 Drought 51 3.2.2
Light and heat 54 3.2.3 Carbon dioxide 56 3.2.4 Ozone 57 3.3 Abiotic stress
and biotic stress 59 3.3.1 Interaction between ABA signaling and MeJA
signaling 59 3.3.2 Interaction with other signaling 60 3.4 C4 plants and
crassulacean acid metabolism 61 3.5 Conclusion 63 4 Root-associated stress
response networks 69 Jennifer P.C. To, Philip N. Benfey, and Tedd D. Elich
4.1 Introduction 69 4.2 Root organization 71 4.2.1 Root developmental zones
71 4.2.2 Root tissue types 73 4.3 Systems analysis of root-associated
stress responses 76 4.4 Root-tissue to system-level changes in response to
stress 78 4.4.1 Nitrogen 78 4.4.2 Salinity 85 4.4.3 Root system
architecture in stress responses 92 4.5 Conclusion 94 5 Plant
low-temperature tolerance and its cellular mechanisms 109 Yukio Kawamura
and Matsuo Uemura 5.1 Introduction 109 5.2 Chilling injury 110 5.2.1 Cold
inactivation of vacuolar H+-ATPase 110 5.2.2 Lipid phase transition (Lalpha
to Lß) 112 5.2.3 Chill-induced cytoplasmic acidification 113 5.2.4
Light-dependent chilling injury 114 5.3 Freezing injury 115 5.3.1
Freeze-induced ultrastructures in the plasma membrane 117 5.3.2 Another
freeze-induced injury of the plasma membrane 118 5.4 Cold acclimation 118
5.4.1 Lipid composition of the plasma membrane during cold acclimation 119
5.4.2 Changes in plasma membrane proteins during cold acclimation 120 5.4.3
Compatible solute accumulation during cold acclimation 120 5.5 Freezing
tolerance 121 5.5.1 Membrane cryostability due to lipid composition 122
5.5.2 Membrane cryostability due to hydrophilic proteins 122 5.5.3
Compatible solutes and freezing tolerance 123 5.5.4 Membrane cryodynamics
and membrane resealing 124 5.5.5 Other membrane cryodynamics 124 5.6
Conclusion 126 6 Salinity tolerance 133 Joanne Tilbrook and Stuart Roy 6.1
Plant growth on saline soils 133 6.1.1 Effects of salt stress on plant
growth 135 6.1.2 Osmotic stress 136 6.1.3 Ionic stress 137 6.2 Tolerance
mechanisms 138 6.2.1 Osmotic tolerance 138 6.2.2 Ionic tolerance 139 6.2.3
Ion exclusion 139 6.2.4 Ion tissue tolerance 140 6.3 Identification of
variation in salinity tolerance 140 6.3.1 Variation in current crops 140
6.3.2 Variation in near wild relatives 141 6.3.3 Variation in model species
143 6.3.4 New phenomic approaches to identify variation in salinity
tolerance 144 6.4 Forward genetic approaches to identify salinity tolerant
loci and candidate genes 144 6.4.1 QTL mapping 144 6.4.2 Transcriptomics
148 6.4.3 Proteomics 149 6.4.4 Metabolomics 150 6.5 Known candidate genes
for salinity tolerance 151 6.5.1 The high-affinity potassium transporter
family 152 6.5.2 The salt overly sensitive pathway 153 6.5.3 Vacuolar
Na+/H+ antiporters and vacuolar pyrophosphatases 154 6.5.4 Osmoprotectants
155 6.5.5 Calcium signaling pathways 155 6.6 Prospects for generating
transgenic crops 156 6.6.1 Overexpression of genes involved with the
transport of ions 158 6.6.2 Manipulation of genes involved in signaling
pathways 159 6.6.3 Altering the expression of genes involved in compatible
solute synthesis 159 6.6.4 The need for cell-type- and temporal-specific
expression 159 6.7 Conclusion 161 7 Molecular and physiological mechanisms
of plant tolerance to toxic metals 179 Matthew J. Milner, Miguel Piñeros,
and Leon V. Kochian 7.1 Introduction 179 7.2 Plant Zn tolerance 181 7.2.1
Physiology of Zn tolerance 181 7.2.2 Molecular biology of Zn tolerance 185
7.2.3 Role of metal-binding ligands in Zn tolerance 188 7.3 Plant Cd
tolerance 190 7.4 Plant aluminum tolerance 190 7.4.1 Physiology of Al
tolerance 190 7.4.2 Molecular biology of Al tolerance 194 7.5 Conclusion
196 8 Epigenetic regulation of abiotic stress responses in plants 203
Viswanathan Chinnusamy, Monika Dalal, and Jian-Kang Zhu 8.1 Introduction
203 8.2 Epigenetic controls of gene expression 204 8.2.1 Establishment of
histone code 205 8.2.2 DNA cytosine methylation 205 8.3 E pigenetic
regulation of abiotic stress responses 210 8.3.1 Stress regulation of genes
for histone modification and RdDM 211 8.3.2 Gene regulation mediated by
stress-induced histone modifications 212 8.3.3 Gene regulation mediated by
stress-induced changes in dna methylation 218 8.3.4 Stress-induced
transposon regulation 219 8.4 Transgenerational inheritance and adaptive
value of epigenetic modifications 220 8.5 Conclusion 221 9 Genomics of
plant abiotic stress tolerance 231 Dong-ha Oh, Maheshi Dassanayake, Hyewon
Hong, Suja George, Seol Ki Paeng, Anna Kroporn ika, Ray A. Bressan, Sang
Yeol Lee, Dae-Jin Yun, and Hans J. Bohnert 9.1 Genomics in plant
research--an introduction 231 9.2 Plant genomes 2012--a transient account
236 9.3 Genomes, transcriptomes, and bioinformatics 237 9.4 Genomes that
inform about abiotic stress 240 9.5 Plants evolved for salinity tolerance
242 9.6 ARMS genomes--Thellungiella genome sequences 244 9.6.1
Lineage-specific gene duplications 244 9.6.2 Divergence of transcriptome
profiles and responses 247 9.6.3 Lineage-specific genes 249 9.7 A breeding
strategy for abiotic stress avoidance 249 9.8 Conclusion 250 10 QTL and
association mapping for plant abiotic stress tolerance: trait
characterization and introgression for crop improvement 257 DELPHINE FLEURY
and Peter Langridge 10.1 Introduction 257 10.2 Genetic mapping of abiotic
stress tolerance traits 260 10.2.1 Quantitative trait loci 260 10.2.2 QTL
for abiotic stress tolerance 262 10.3 Association mapping of abiotic stress
tolerance traits 263 10.3.1 Linkage disequilibrium and population structure
263 10.3.2 Association study of abiotic stress tolerance 264 10.4 Transfer
of QTL findings to breeding programs 265 10.5 Issues in genetic analysis of
abiotic stress tolerance 268 10.5.1 Phenotyping methods 268 10.5.2
Selection of germplasm for genetic analysis 270 10.5.3 Stability of QTL
across environments 272 10.6 Current directions of quantitative genetics
for abiotic stress tolerance 274 10.6.1 Physiological components of abiotic
stress tolerance QTL 274 10.6.2 Integration of physiological components
into abiotic stress tolerance QTL 275 10.6.3 Meta QTL 276 10.6.4 New
population designs for QTL mapping 276 10.7 Conclusion 279 Index 289 Color
plate section is located between pages 132 and 133