Mechanism of Plant Hormone Signaling under Stress: A Functional Genomic Frontier

INDICE: About the author .List of Contributors .Preface .Part I: Action of phytohormones in stress .Chapter 1: Auxin as a mediator of abiotic stress responsesBranka Salopek–Sondi, Iva Pavloviæ, Ana Smolko, Dunja amec .1.1. Introduction .1.2. Auxin: short overview of appearance, metabolism, transport and analyticsToluene production as a case study .1.3. How auxin homeostasis shifts upon diverse abiotic stresses? .1.4. How does auxin signaling respond to abiotic stress? .1.5. Auxin and redox state during abiotic stress .1.6. Auxin–stress hormones crosstalk in stress condition .1.7. Promiscuous protein players of plant adaptation: biochemical and structural views .1.8. Conclusion .References .Chapter 2 : Mechanism of Auxin mediated stress signaling in plantsLekshmy S, Krishna K G, Jha S.K, Sairam R.K .2.1 Introduction .2.2 Auxin biosynthesis, homeostasis and signaling .2.3 Auxin mediated stress responses in model and crop plants .2.4 Regulation of root system architecture under drought and nutrient stresses .2.5 Conclusions and future perspectives .References .Chapter 3: Integrating the Knowledge of Auxin Homeostasis with Stress Tolerance in PlantsShivani Saini, Isha Sharma, Pratap Kumar Pati .3.1 Introduction .3.2 Auxin transport and its role in plant stress .3.3 Auxin signaling and its role in plant stress .3.4 Auxin conjugation and degradation and its role in plant stress .3.5 Conclusion .References .Chapter 4:  Cytokinin signaling in plant response to abiotic stressesNguyen Binh Anh Thu, Xuan Lan Thi Hoang, Mai Thuy Truc, Saad Sulieman, Nguyen Phuong Thao, Lam–Son Phan Tran .4.1. Introduction .4.2. CK metabolism .4.3. The components of CK signaling pathway .4.4. CK signaling in plant responses to the abiotic stresses .4.5. Genetic engineering of CK content for improvement of plant tolerance to abiotic stresses .4.6. Conclusions .References .Chapter 5:  Cross talk between gibberellins and abiotic stress tolerance machinery in plantsAshutosh Sharan, Jeremy Dkhar, Sneh Lata Singla–Pareek, Ashwani Pareek .5.1. Introduction  .5.2. Gibberellins: biosynthesis, transport and signaling .5.3. GA metabolism and signaling during abiotic stress .5.4. Cross–talk between GA and other plant hormones in response to abiotic stresses .5.5. Applications in crop improvement .5.6. Conclusion .Acknowledgement .References   .Chapter 6: The crosstalk of GA and JA: a fine–tuning on balance of plant growth, development and defenseYuge Li, and Xingliang Hou .6.1. Introduction .6.2. GA pathway in plants .6.3. JA pathway in plants .6.4. GA antagonizes JA–mediated defense .6.5. JA inhibits GA–mediated growth .6.6. GA and JA synergistically mediate plant development .6.7. Conclusion .References .Chapter 7: JASMONATE SIGNALLING AND STRESS MANAGEMENT IN PLANTS.Sirhindi Geetika, Mushtaq Ruqia, Sharma Poonam, Kaur Harpreet and Ahmad Mir Mudaser .7.1. Introduction .7.2. Ja Biosynthesis And Metabolic Fate .7.3. Ja Signaling Network .7.4. Physiological Role Of Jas .7.5. Ja Regulated Stress Responses .7.6. Conclusion .Bibliography .References .Chapter 8: Mechanism of ABA signaling in response to abiotic stress in plantsAnkush Ashok Saddhea, Kundan Kumar and Padmanabh Dwivedi .8.1. Introduction .8.2. Signal perception and ABA receptor .8.3. Negative regulator of ABA signaling: Protein phosphatase 2C (PP2C) .8.4. Positive regulator of ABA signaling: SnRK2 .8.5. ABA signaling regulating transcription factor .8.6. Cross talks between various ABA responsive pathways in abiotic stress .8.7. Summary and future prospects .References .Chapter 9:  Abscisic acid signaling and involvement of mitogen activated protein kinases and calcium–dependent protein kinases during plant abiotic stressAryadeep Roychoudhury, Aditya Banerjee .9.1. Introduction .9.2. ABA signaling in plants .9.3. The signalosome and signaling responses mediated by ABA: Structural alterations in ABA by PYR/PYL/RCAR .9.4. Structural alterations during PP2C inhibition by ABA .9.5. The abi1–1 mutation mystery solved .9.6. Basic leucine zipper (bZIP) TFs in ABA signaling  .9.7. Mitogen–activated protein kinase (MAPK) cascades and regulation of downstream signaling .9.8. Calcium Dependent Protein Kinases (CDPKs): a group of MAPK .9.9. MAPK–CDPK cross–talk .9.10. Conclusion and future perspectives .References .Chapter 10:  Abscisic acid activates pathogenesis–related defence gene signaling in LentilRebecca Ford, David Tan, Niloofar Vaghefi, Barkat Mustafa .10.1. Plant host defence mechanisms .10.2. The role of plant hormones in pathogen defense .10.3. The lentil–Ascochyta lentis pathosystem .10.4. Key defense–related genes involved in Ascochyta lentis defense .10.5. The effect of exogenous hormone treatment on PR4 and PR10 transcription in lentil .10.6. Conclusion .References .Chapter 11: Signaling and modulation of non–coding RNAs in plants byAbscisic Acid (ABA)Raj Kumar Joshi, Swati Megha, Urmila Basu, Nat N.V.Kav11.1. Introduction .11.2. Biogenesis of non–coding RNAs in plant .11.3. Mode of action ofncRNAs in plants .11.4. ABA signaling in plants .11.5. Non–coding RNAs and ABA response .11.6. Conclusion and future prospects .References .Chapter 12: Ethylene and stress mediated signaling in plants: a molecular perspectivePriyanka Agarwal, Gitanjali Jiwani, Ashima Khurana, Pankaj Gupta and Rahul Kumar .12.1. Introduction .12.2. Type of stress .12.3. Overview of stress signaling .12.4. Perception of stress .12.5. Action of different secondary messengers .12.6. Ca2+ as an intermediate signal molecule .12.7. Role of MAPK phosphoproteins in stress signaling .12.8. Role of ethylene during stress .12.9. Role of ethylene in abiotic stress .12.10. Role of ethylene in biotic stress .12.11. Role of ABA in stress .12.12. Role of other phytohormones in stress .12.13. Conclusion .Acknowledgement .References .Chapter 13: Regulatory Function of Ethylene in Plant Responses to Drought, Cold and Salt StressesHaixia Pei, Honglin Wang, Lijuan Wang, Fangfang Zheng and Chun–Hai Dong .13.1. Functional Roles of Ethylene in Plant Drought Tolerance .13.2. Ethylene Signaling in Plant Cold Tolerance .13.3. Ethylene Signaling and Response to Salt Stress .13.4. Conclusion .References .Chapter 14: Plant nitric oxide signaling under environmental stressesIone Salgado, Halley Caixeta Oliveira and Marília Gaspar .14.1. Introduction .14.2. Mechanisms of NO action in Plants .14.3. The Control of NO Homeostasis in Plants .14.4. NO and the Response to Abiotic Stresses .14.5. Conclusions and Future Prospects .References .Chapter 15: Cell Mechanisms of Nitric Oxide Signaling in Plants under Abiotic Stress ConditionsYuliya A. Krasylenko, Alla I. Yemets and Yaroslav B. Blume .15.1. Introduction .15.2. Duality of RNS: key secondary messengers in plant cell versus nitrosative stress agents .15.3. Tyrosine nitration as a hallmark of nitrosative stress and regulatory posttranslational modification .15.4. NO and environmental abiotic challenges .15.5. Conclusions and future perspectives .References .Chapter 16: S–nitrosylation in abiotic stress in plants and nitric oxide interaction with plant hormonesAnkita Sehrawat and Renu Deswal .16.1. Introduction .16.2. S–nitrosylation in abiotic stress .16.3. 2.5 Cadmium stress and 2,4–dichlorophenoxy acetic acid (2,4–D) stress .16.4. Nitric oxide and plant hormones interaction .16.5. Conclusions and Future area of research .References .Chapter 17: Salicylic Acid signaling and its role upon responses to stresses in plantsPingzhi Zhao, Gui–Hua Lu, Yong–Hua Yang17.1. Introduction .17.2. Salicylic acid biosynthesis and metabolism in plants .17.3. Salicylic acid: a central molecule in plant responses to stress .17.4. Salicylic acid in relation to other phytohormones in response to plant stress status .17.5.Conclusion .References .Chapter 18: Glucose and brassinosteroid signaling network in controlling plant growth and development under different environmental conditionsManjul Singh, Aditi Gupta and Ashverya Laxmi .18.1. Introduction. .18.2. Glucose homeostasis and signaling in plants .18.3. Brassinosteroid biosynthesis and signalling .18.4. Role of Glc in plant adaptation to changing environmental conditions .18.5. Role of BR in plant adaptation to changing environmental conditions .18.6. Glc–BR crosstalk and its adaptive significance in plant development .18.7. Conclusion and future prospective .References .INDEX .About the author .List of Contributors .Preface .Part II: Interaction of other components with phytohormone .Chapter 1: Interaction between hormone and redox signaling in plants: Divergent pathways and convergent rolesSrivastava AK, Redij T, Sharma B, Suprasanna .1.1. Introduction .1.2. Redox–hormone crosstalk in plants .1.3. Auxin .1.4. Abscisic acid .1.5. Ethylene .1.6. Jasmonic acid .1.7. Salicylic acid .1.8. Brassinosteroid .1.9. Conclusion and future perspectives .References .Chapter 2: Redox regulatory networks in response to biotic stress in plants: A new insight through chickpea–Fusarium interplayAnirban Bhar, Sumanti Gupta, Moniya Chatterjee and Sampa Das .2.1. Introduction .2.2. Production and scavenging of ROS: The balance vs. Perturbations .2.3. Role of ROS in plants: ease and disease .2.4. Reactive oxygen species networks in plants .2.5. ROS signaling in Chickpea– Fusarium interplay .2.6. Concluding remarks .2.7. Acknowledgements .References .Chapter 3: Ca2+ the Miracle Molecule in Plant Hormone Signaling during Abiotic StressSwatismita Dhar Ray .3.1. Introduction  .3.2. Intricacy Of Hormonal Signaling In Abiotic Stress .3.3. Ca2+ Regulated Hormonal Signaling  .3.4. Calreticulin (Crt)  .3.5. Conclusion  .Acknowledgement  .References  .Chapter 4: Phosphoglycerolipid signaling in response to hormones under stressPokotylo Igor, Janda Martin, Kalachova Tetiana, Zachowski Alain & Ruelland Eric .4.1.  Main players in the phosphoglycerolipid signaling machinery .4.2. Lipid signaling, an important component of plant stress responses .4.3. Involvement of phosphoglycerolipids in phytohormone signaling .4.4 Stresses can affect the responses to hormones by altering the phosphoglycerolipid machinery .4.5 Conclusion .References .Chapter 5: The Role of Plant Cytoskeleton on Phytohormone Signaling under Abiotic and Biotic StressesYaroslav B. Blume, Yuliya A. Krasylenko and Alla I. Yemets .5.1. Introduction .5.2. Phytohormone–mediated perception of abiotic factors via cytoskeleton .5.3. Cytoskeleton regulation in plant interactions with pathogens/symbionts: jasmonic,  salycilic acids and strigolactones .5.4. Conclusions and Future Perspectives .Acknowledgements. .References .Chapter 6: Proteins in phytohormone signaling pathways for abiotic stress in plantsSasikiran Reddy Sangireddy, Zhujia Ye, Sarabjit Bhatti, Xiao Bo Pei, Muhammad Younas Khan Barozai, Theodore Thannhauser, Suping Zhou .6.1. Introduction .6.2. Metabolic pathways of phytohormones and stress–induced protein expression  affecting their biosynthesis process .6.3. Proteins for intra–and inter–cellular transport of phytohormones .6.4. Hormone signaling systems, hormone cross talk and stress responses .6.5. The application of proteomics in the identification of hormone signaling pathways .6.6. Conclusion and prospective  .References .Chapter 7: Perturbation and disruption of plant hormone signaling by organic xenobiotic pollutionsAnne–Antonella Serra, Diana Alberto, Fanny Ramel, Gwenola Gouesbet, Cécile Sulmon, Ivan Couée .7.1. Introduction .7.2. Plant–hormone–interfering naturally–occurring organic compounds play important roles in the chemical ecology of plants .7.3. Transcriptome profiling reveals the wide–ranging molecular effects of plant–organic xenobiotic interactions .7.4. The wide–ranging molecular effects of plant–organic xenobiotic interactions emphasize the involvement of regulatory processes .7.5. Specifically–designed organic xenobiotics directly interact with plant hormone systems .7.6. Organic xenobiotics can cause biological effects that interfere with plant hormone dynamics and signalling .7.7. The diversity of organic xenobiotic occurrences in environmental pollutions can induce plant hormone perturbations in non–target plant communities .7.8.Conclusions and perspectives .References .Chapter 8: Plant hormone signaling mediates plant growth plasticity in response to metal stressXiangpei Kong, Huiyu Tian, Zhaojun Ding .8.1. Introduction .8.2. Cadmium (Cd) .8.3. Aluminum (Al) .8.4. Other metals .References .Part III: Transcriptional regulators of phytohormones .Chapter 9: Transcription factors and hormone–mediated mechanisms regulate stomata development and responses under abiotic stresses: an overviewMarco Landi, Alice Basile, Marco Fambrini, Claudio Pugliesi .9.1. Introduction .9.2. Stomata development .9.3. Stomatal response to drought/salinity and waterlogging/anoxia constraints .9.4. Conclusions and perspectives .References .Chapter 10: Convergence of stress–induced hormone signaling pathways on a transcriptional co–factorNidhi Dwivedi, Vinay Kumar and Jitendra K. Thakur .10.1. Introduction .10.2. Mediator complex .10.3. Role of Mediator in transcription .10.4. Flexibility of Mediator complex .10.5. Phytohormone signaling under stress .10.6. Effect of hormone and stress on the expression of Mediator subunit genes .10.7. Involvement of Mediator subunits in hormone signaling and stress response .10.8. Convergence of signaling pathways on Mediator complex .10.9. Conclusion .References .Chapter 11: Micro–Regulators of Hormones and StressNeha Sharma, Deepti Mittal and Neeti–Sanan Mishra .11.1. Introduction .11.2. Plant miRs .11.3. Role of miRs in hormone signaling .11.4. miR–mediated regulation of abiotic stress .11.5. Conclusions and Perspectives .References .Part IV: Involvement of multiple phytohormones in stress response .Chapter 12: Signal transduction components in guard cells during stomatal closure by plant hormones and microbial elicitorsNeha Sharma, Deepti Mittal and Neeti–Sanan Mishra .12.1. Introduction .12.2. Compounds that regulate stomatal function .12.3. Guard cell turgor and stomatal closure: Ion fluxes as the basis .12.4. Experimental approaches to study the signaling components .12.5. Sensing systems in guard cells .12.6. Signaling components in guard cells .12.7. Validation with Arabidopsis mutants .12.8. Concluding remarks .References .Chapter 13: Plant s defense and survival strategies versus pathogen s anti–defense and infection capability: The hormone–based mechanismsPranav Pankaj Sahu, Namisha Sharma and Manoj Prasad .13.1. Introduction .13.2. Modulation of hormone signaling network by pathogens for virulence .13.3. Alteration of hormone signaling network by plants for disease resistance .13.4. Conclusions and future perspectives .References .Chapter 14: Exploring crossroads between seed development and stress–responseSushma Naithani, Hiro Nonogaki and Pankaj Jaiswal .14.1. Introduction .14.2. Genes, proteins, and pathways involved in seed development .14.3. Genes at Intersection of Seed Development and Stress–response .14.4. Exploring Bioinformatics resources .14.5. Insights and Future Prospects .14.6. Acknowledgement .14.7. Bibliography .Chapter 15: Role of Multiple Phytohormones in Regulating Stress Responses in PlantsDiwaker Tripathi, Dhirendra Kumar, Bal Krishna Chand Thakuri .15.1. Introduction .15.2. Biotic Stress .15.3. Role of Hormones in Abiotic Stress .15.4. Interaction of SA with other Stress Hormones .15.5. SA/ABA Antagonism .15.6. Future Perspective and Challenges .References .Chapter 16: Phytohormone and Drought stress: Plant Responses to Transcriptional RegulationNeha Pandey, Zahra Iqbal, Bhoopendra K. Pande, Samir V. Sawant .16.1. Introduction .16.2. PHYTOHORMONES: Role in plant growth and development .16.3. Plant Hormonal response to stress condition .16.4. Hormonal mediated transcriptional response to stress condition .16.5. Phytohormones mediated signaling response under stress condition .16.6. Significance of Phytohormones in plant genetic engineering .16.7. Conclusion .References .Chapter 17: Mechanisms of hormone signaling in plants under abiotic and biotic stressesJogeswar Panigrahi  and Gyana Ranjan Rout .17.1. Introduction .17.2. Role of hormone in plant growth and development .17.3. Common tenets in hormone signaling in plants under abiotic and biotic stress .17.4. Role of ROS in hormone signaling pathways  .17.5. Role of MAPK in hormone signaling pathways .17.6. Role of Jasmonic acid and cytokinin on hormone signaling pathways .17.7. Role of Brassinosteroid on hormone signaling pathways .17.8. The cross talk of hormones and hormone like substances in plants under abiotic and biotic stress response .17.9. Conclusion .Reference .Chapter 18: Transgenic Approaches to Improve the Crop Productivity via Phytohormonal Research: A Focus on Mechanism of Phytohormone ActionBrijesh Gupta, Rohit Joshi, Ashwani Pareek, Sneh L. Singla–Pareek .18.1. Introduction .18.2. Phytohormones and crop yield: approaches and vision for genetic improvement .18.3.  Manipulation of phytohormone levels in transgenic plants .18.4. Phytohormonal crosstalks to enhance crop productivity .18.5. Conclusion and future directions .18.6. Acknowledgements .References .INDEX

• ISBN: 978-1-118-88892-6
• Editorial: Wiley–Blackwell
• Encuadernacion: Cartoné
• Páginas: 1104
• Fecha Publicación: 10/04/2017
• Nº Volúmenes: 1
• Idioma: Inglés