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000771065 019__ $$a957616158
000771065 020__ $$a9783319432786$$q(electronic book)
000771065 020__ $$a3319432788$$q(electronic book)
000771065 020__ $$z9783319432762
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000771065 050_4 $$aQK898.P8
000771065 08204 $$a572.6$$223
000771065 24500 $$aAgricultural proteomics.$$nVolume 2,$$pEnvironmental stresses /$$cGhasem Hosseini Salekdeh, editor.
000771065 24630 $$aEnvironmental stresses
000771065 264_1 $$aSwitzerland :$$bSpringer,$$c[2016]
000771065 300__ $$a1 online resource.
000771065 336__ $$atext$$btxt$$2rdacontent
000771065 337__ $$acomputer$$bc$$2rdamedia
000771065 338__ $$aonline resource$$bcr$$2rdacarrier
000771065 504__ $$aIncludes bibliographical references and index.
000771065 5050_ $$aPreface; Contents; Contributors; 1 Well-Designed Experiments Make Proteomic Studies on Stressed Plants Meaningful; Abstract; 1.1 Introduction; 1.2 Designing Experiments to Mimic Abiotic Stress Observed in the Field; 1.2.1 Salt; 1.2.2 Drought; 1.2.3 Thermal Stress; 1.2.4 Waterlogging; 1.3 Managing Interactions Between Abiotic Stresses; 1.4 General Principles for the Design of 'Stress' Experiments; 1.4.1 The Importance of Time; 1.4.2 The Importance of Tissue Sampling; 1.5 How Do Acclimation and Shock Differ?; Acknowledgments; References.
000771065 5058_ $$a2 Cereal Root Proteomics for Complementing the Mechanistic Understanding of Plant Abiotic Stress ToleranceAbstract; 2.1 Introduction; 2.1.1 Drought; 2.1.2 Salinity; 2.1.3 Cold; 2.1.4 Heat; 2.1.5 Flooding; 2.1.6 Heavy Metal Toxicity; 2.1.7 Nutrient Deficiency; 2.2 Conclusions; References; 3 A Proteomic View of the Cereal and Vegetable Crop Response to Salinity Stress; Abstract; 3.1 The Physiological Response to Salinity Stress; 3.2 Adaptive Mechanisms for Salt Tolerance; 3.3 Salinity Stress Limits the Production of Cereal and Vegetable Crops.
000771065 5058_ $$a3.3.1 The Proteomic Response of Cereals to Salinity Stress3.3.2 The Proteomic Response of Vegetables to Salinity Stress; 3.4 Conclusion and Future Perspectives; Acknowledgments; References; 4 Proteomics of Flooding-Stressed Plants; Abstract; 4.1 Introduction; 4.2 Proteomic Analyses of Plants Under Flooding Stress; 4.2.1 Soybean; 4.2.2 Wheat; 4.2.3 Rice; 4.2.4 Tomato; 4.2.5 Maize; 4.3 Organ-Specific Proteomics of Flooding-Stressed Plants; 4.3.1 Leaf; 4.3.2 Root; 4.4 Proteins Regulated Under Flooding Stress; 4.4.1 Proteins Related to Glycolysis and Fermentation; 4.4.2 Energy-Related Proteins.
000771065 5058_ $$a4.4.3 Reactive Oxygen Species Scavenging-Related Proteins4.4.4 Cell Wall Loosening-Related Proteins; 4.4.5 Ubiquitination Proteasome-Related Proteins; 4.4.6 Proteins Regulated During Recovery from Flooding Stress; 4.5 Conclusion and Future Prospective; Acknowledgments; References; 5 Proteomic Analysis of Crop Plants Under Low Temperature: A Review of Cold Responsive Proteins; Abstract; 5.1 Introduction; 5.2 Proteomics Tools and Techniques; 5.3 Cold Stress Response Proteins in Plants; 5.3.1 Cold-Regulated Proteins; 5.3.2 Antifreeze Proteins.
000771065 5058_ $$a5.3.3 Oxidative Stress and ROS Scavenging Related Proteins5.3.4 Photosynthesis Related Proteins; 5.3.5 Carbohydrate Metabolism Related Proteins; 5.3.6 Proteins Related to Protein Synthesis and Metabolism; 5.3.7 Proteins Related to Energy Metabolisms; 5.3.8 Signaling and Gene Regulatory Proteins; 5.4 Conclusion and Future Perspectives; References; 6 How Proteomics Contributes to Our Understanding of Drought Tolerance; Abstract; 6.1 Introduction; 6.2 Rice and Water Deficits; 6.2.1 Panicle Exsertion and Spikelet Sterility; 6.2.2 Panicle Proteome; 6.2.3 Grain Filling and Inferior Spikelets.
000771065 506__ $$aAccess limited to authorized users.
000771065 520__ $$aThis book will cover several topics to elaborate how proteomics may contribute in our understanding of mechanisms involved in stress adaptation. The knowledge being accumulated by a wide range of proteomics technologies may eventually be utilized in breeding programs to enhance stress tolerance. This book presents comprehensive reviews about responses of crop and farm animals to environmental stresses. Challenges related to stress phenotyping and integration of proteomics and other omics data have also been addressed. According to FAO?s estimate, the number of people suffering from chronic hunger has increased to over a billion. Due to most of the extreme poor who suffers from hunger live in rural areas, the effort to enhance agricultural productivity will be a key element in reducing the number of global population suffering from hunger. This goal will not be achieved unless we develop new genotypes of food crops and animals that will both improve production under sub-optimal conditions. The discovery of genotypes with the capacity to cope with these problems suggests that increasing the support of breeding for fragile environments is a viable strategy for uplifting the rural poor. However, breeding for environmental stresses, is a slow and inefficient process. Also several genotypes with good stress tolerance environmental stresses have been identified or developed, it is difficult to transfer these traits into elite backgrounds because they are genetically very complex. One possibility currently being evaluated for enhancement of stress tolerance is to apply biomarkers in breeding programs to follow the inheritance of major genes that are difficult to phenotype, such as pyramids of disease resistance genes of similar effect. Proteomics is a powerful approach to identify proteins associated with stress tolerance. It offers an entry point for identifying possible significant changes in protein levels against a background of unresponsive proteins. The application of proteomics is usually initiated by detection of stress responsive proteins thought comparison between stressed and control organisms. Identification of these expressional candidate proteins may then reveal that some of them have functions clearly consistent with the stress tolerance trait. Other relevant information including the expression pattern at mRNA and metabolomics may help to further verify the correlation of these candidate proteins with desirable traits. The step forward from collecting proteomics data to functional prediction will pave the way for the sustainable agricultural production under unfavorable environmental conditions.
000771065 588__ $$aOnline resource; title from PDF title page (viewed August 29, 2016).
000771065 650_0 $$aPlant proteomics.
000771065 650_0 $$aCrops$$xEffect of stress on.
000771065 650_0 $$aCrop improvement.
000771065 650_0 $$aAgricultural ecology.
000771065 7001_ $$aSalekdeh, Ghasem Hosseini,$$eeditor.
000771065 85280 $$bebk$$hSpringerLink
000771065 85640 $$3SpringerLink$$uhttps://univsouthin.idm.oclc.org/login?url=http://link.springer.com/10.1007/978-3-319-43278-6$$zOnline Access$$91397441.1
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