Temperature and plant development/ (Record no. 180128)

MARC details
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fixed length control field 00327nam a2200121Ia 4500
040 ## - CATALOGING SOURCE
Transcribing agency CUS
082 ## - DEWEY DECIMAL CLASSIFICATION NUMBER
Classification number 581.3
Item number FRA/T
245 #0 - TITLE STATEMENT
Title Temperature and plant development/
Statement of responsibility, etc. edited by Feara A. Franklin,
260 ## - PUBLICATION, DISTRIBUTION, ETC. (IMPRINT)
Place of publication, distribution, etc. New York:
Name of publisher, distributor, etc. Wiley Blackwell,
Date of publication, distribution, etc. 2014.
300 ## - PHYSICAL DESCRIPTION
Extent 226 p.
505 ## - FORMATTED CONTENTS NOTE
Formatted contents note <br/>1 Temperature sensing in plants 1<br/>Steven Penfield and Dana MacGregor<br/>1.1 Introduction 1<br/>1.2 Passive and active temperature responses in plants 1<br/>1.3 Temperature sensing during transcriptional regulation 3<br/>1.4 Sensing cold: A role for plasma membrane calcium channels<br/>in plants 8<br/>1.5 A role for membrane fluidity as an upstream<br/>temperature sensor? 11<br/>1.6 Temperature sensing by proteins 12<br/>1.7 Summary 14<br/>2 Plant acclimation and adaptation to cold environments 19<br/>Bob Baxter<br/>2.1 Introduction 19<br/>2.2 Chilling and freezing injury 20<br/>2.3 Freezing avoidance and tolerance at the structural<br/>and physiological level 21<br/>2.3.1 Freezing avoidance 21<br/>2.3.2 Freezing point depression, supercooling, deep<br/>supercooling, and extracellular and extraorgan freezing 23<br/>2.3.3 Ice nucleation and structural and thermal ice barriers 23<br/>2.3.4 Glass transition (vitrification) 25<br/>2.3.5 Antifreeze factors 25<br/>2.4 Freezing tolerance 26<br/>2.4.1 Cold acclimation (hardening) 26<br/>2.4.2 Genes and regulatory mechanisms in cold acclimation 27<br/>2.4.3 Dehydrins 30<br/>2.4.4 Heat shock proteins 30<br/>2.4.5 Enzymatic and metabolic response in cryoprotection 30<br/>2.4.6 The role of hormones in low-temperature acclimation 31<br/>' ox<br/>vi CONTENTS<br/>2.5 Cold deacclimation (dehardening) and reacclimation<br/>(rehardening)<br/>2.6 Spatial and temporal considerations of plant responses to<br/>low temperature 34<br/>2.6.1 Interactions between cold and light:<br/>Winter dormancy 35<br/>2.6.2 Interactions between cold and environmental drought 36<br/>2.6.3 Interactions between cold and light: Photosynthesis,<br/>photoinhibition, and reactive oxygen species in cold<br/>environments 36<br/>2.7 The survival of cold and freezing stress in a changing climate 38<br/>2.8 Plant cold acclimation and adaptation in an agricultural<br/>context •<br/>2.9 Summary 4-<br/>3 Plant Acclimation and adaptation to warm environments 49<br/>Martijn van Zanten, Ralph Bours, Thijs L. Pons,<br/>and Marcel C.G. Proveniers<br/>3.1 Introduction<br/>3.2 Implications of high temperature for agriculture and<br/>natural ecosystems<br/>3.3 Temperature perception and signaling pathways 52<br/>3.4 Photosynthesis ^3<br/>3.5 Respiration and carbon balance 57<br/>3.6 Growth and allocation of biomass 58<br/>3.7 Architectural changes in response to high temperature 58<br/>3.7.1 Heat-induced hyponastic growth in Arabidopsis<br/>and hormonal and light control 59<br/>3.7.2 High-temperature-induced hypocotyl elongation in<br/>Arabidopsis 60<br/>3.7.3 PIF4 as central regulator of high-temperature<br/>acclimation in61<br/>3.8 Hormonal regulation of thermotolerance 62<br/>3.9 Functional implications of plant architectural changes<br/>to high temperature 63<br/>3.10 Interactions between drought and high temperature 64<br/>3.11 Carbohydrate status control of plant acclimation to<br/>high temperature 65<br/>3.12 Thermoperiodic effects on plant growth<br/>and architecture 66<br/>3.13 High-temperature effects on the floral transition 68<br/>CONTENTS Vll<br/>4 Vernalization: Competence to flower provided by winter 79<br/>Dong-Hwan Kim and Sibum Sung<br/>4.1 Introduction 79<br/>4.2 Vernalization requirement in Arabidopsis 80<br/>4.2.1 Molecular basis of Fi?/-mediated FLCactivation 81<br/>4.2.2 Mutations in autonomous pathway genes: Another<br/>route to confer vernalization requirement 82<br/>4.2.3<br/>Other chromatin-remodeling complexes required for FLC<br/>activation 83<br/>4.3 The molecular mechanism of vernalization 84<br/>4.3.1 Vernalization-mediated epigenetic repression of FLC 84<br/>4.3.2 The dynamics of PRC2 and TRX at FLC chromatin 86<br/>4.3.3 Mechanisms underlying PRC2 recruitment to FLC<br/>chromatin by vernalization 87<br/>4.4 Resetting of FLC repression during meiosis 88<br/>4.5 Vernalization in other plant species 89<br/>4.5.1 Arabis Alpina 89<br/>4.5.2 Cereals (wheat and barley) 90<br/>4.5.3<br/>Sugar beet {Beta vulgaris) 90<br/>4.6 Concluding remarks 91<br/>5 Temperature and light signal integration 97<br/>Harriet G. McWatters, Gabriela Toledo-Ortiz, and Karen J. Halliday<br/>5.1 Introduction 97<br/>5.2 Convergence points for light and temperature sensing 101<br/>5.3 Phytochrome-Interacting Factors as signal integrators 102<br/>5.4<br/>ELONGATED HYPOCOTYL 5 (HY5): A cool operator 105<br/>5.5 Light and temperature converge at the circadian oscillator 107<br/>5.6 Photoperiodic and thermal control of flowering 113<br/>5.7 Light-dependent circadian gating of cold-acclimation<br/>responses 115<br/>5.8 Temperature and light regulation of cell membrane fatty<br/>acid composition 117<br/>5.9 Concluding thoughts: Implications for a changing future 118<br/>6 Temperature and the circadian clock 131<br/>Kathleen Greenham and C. Robertson McClung<br/>6.1 Introduction 131<br/>6.2 Temperature compensation 136<br/>viii CONTENTS<br/>6.3 Temperature entrainment 142<br/>6.4 Cold tolerance ^46<br/>6.5 Splicing<br/>6.6 Concluding remarks 151<br/>7 Temperature and plant immunity 163<br/>Jian Hua<br/>7.1 Introduction 163<br/>7.2 Plant immunity 164<br/>7.2.1 Immunity against microbial pathogens 164<br/>7.2.2 Immunity against necrotrophic pathogens 166<br/>7.2.3 Immunity against herbivorous insects 166<br/>7.2.4 Immunity against viruses 167<br/>7.3 Temperature effects on plant disease resistance 167<br/>7.3.1 High-temperature suppression of disease resistance 168<br/>7.3.2 Low-temperature inhibition of plant immunity 169<br/>7.3.3 Disease resistance induced by high and low<br/>temperatures 169<br/>7 4 The molecular basis for temperature sensitivity in plant<br/>immunity ^<br/>7.4.1 Heat-sensitive NB-LRR R proteins 170<br/>7.4.2 Involvement of NB-LRR R proteins in heat-sensitive<br/>immune responses 172<br/>7 4 3 Enhancement of immunity by ABA deficiency at high<br/>temperatures ''<br/>7.4.4 Cold sensitivity in RNA silencing-mediated immunity 173<br/>7.5 Evolution of the temperature sensitivity of immunity 174<br/>7.5.1 Coevolution with pathogens 175<br/>7.5.2 Competition between biotic and abiotic responses 176<br/>7.6 Concluding remarks 17-6<br/>8 Temperature, climate change, and global food security 181<br/>Robert J. Redden, Jerry L. Hatfield, RV. Vara Prasad,<br/>Andreas W. Ebert, Shyam S. Yadav, and GarryJ. O'Leary<br/>8.1 Introduction 1^1<br/>8.2 Climate change on a global basis 181<br/>8.3 The impact of temperature on crop water relations 183<br/>8.4 The influence of high temperature on crop physiology<br/>and yield processes 1^6<br/>1 70<br/>CONTENTS ix<br/>8.5 The Interaction of climate change factors on crop<br/>development 188<br/>8.5.1 The interaction of rising temperature and CO, 188<br/>8.5.2 The interaction of high-temperature and<br/>drought stress 189<br/>8.6 The Impact of global climate change on food quality<br/>and plant nutrient demand 190<br/>8.7 Breeding high-temperature stress tolerance using crop<br/>wild relatives 190<br/>8.8 Global food production and food security 191<br/>8.8.1 ^\'heat production 192<br/>8.8.2 Rice production 192<br/>8.8.3 Potato production 192<br/>8.8.4 Maize production 193<br/>8.8.5 Sorghum production 193<br/>8.8.6 Cassava production I93<br/>8.8.7 Pulse production I93<br/>8.8.8 Predicted impacts of climate change on global crop<br/>production I94<br/>8.9 Crop nutritional content 194<br/>8.10 Discussion 196<br/>8.11 Conclusions I97<br/>Index 203<br/>Colorplatesection is located between pages 130 and 131.
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        Central Library, Sikkim University Central Library, Sikkim University General Book Section 29/08/2016 581.3 FRA/T P35140 29/08/2016 General Books
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