Key features:
Serves as a cutting-edge resource for researchers and students who are studying plant abiotic stress tolerance and crop improvement through metabolic adaptations Presents the latest trends and developments in the field of metabolic engineering and abiotic stress tolerance Addresses the adaptation of plants to climatic changes Gives special attention to emerging topics such as the role of secondary metabolites, small RNA mediated regulation and signaling molecule responses to stresses Provides extensive references that serve as entry points for further research Metabolic Adaptations in Plants during Abiotic Stress covers a topic of past, present and future interest for both scientists and policy makers as the global challenge of climate change is addressed. Understanding the mechanisms of plant adaptation to environmental stresses can provide the necessary tools needed to take action to protect them, and hence ourselves. This book brings together recent findings about metabolic adaptations during abiotic stress and in diverse areas of plant adaptation. It covers not only the published results, but also introduces new concepts and findings to offer original views on the perspectives and challenges in this field.
Contents
Foreword.....................................................................
.............................................................................
................................................xi
Acknowledgments..............................................................
.............................................................................
...................................... xiii
Editors......................................................................
.............................................................................
..................................................xv
Contributors.................................................................
.............................................................................
........................................... xvii
Section I Abiotic Stress Management and Its Impact on Plants
1. Effects of Different Abiotic Stresses on Primary
Metabolism...................................................................
................................3
Belen Colavolpe, Fabiana Espasandin, Juan Manuel Vilas, Santiago Maiale,
Pedro Sansberro, and Oscar A. Ruiz
2. Metabolic Adaptation and Allocation of Metabolites to Phloem Transport and
Regulation Under Stress........................21
Kathryn Dumschott, Andrew Merchant, and Millicent Smith
3. Mechanism of Salt Stress Tolerance and Pathways in Crop
Plants.......................................................................
..................27
Manu Kumar and Mahipal Singh Kesawat
4. Recent Advances on the Modulatory Role of ATPases toward Salt Tolerance in
Plants.......................................................45
Soumya Mukherjee
5. Physiological and Phenological Responses of Crop Plants under Heat
Stress.......................................................................
55
Allah Ditta
6. Biochemical and Molecular Mechanisms of HighTemperature Stress in Crop
Plants........................................................65
Gurpreet Kaur, Bavita Asthir, and N.S. Bains
7. Profiles of Antioxidant Isoenzymes and Physiological Behavior of Tomato
Exposed to NaCl Stress and Treated
with Salicylic
Acid.........................................................................
.............................................................................
...................73
Salma Wasti, Nizar Dhaoui, Ibtissem Medyouni, Hajer Mimouni, Hela Ben Ahmed,
and Abdellah Chalh
8. Toxicity of Heavy Metal and Its Mitigation Strategies through Application
of Nutrients, Hormones,
and
Metabolites..................................................................
.............................................................................
..............................81
Rachana Singh, Parul Parihar, Anita Singh, and Sheo Mohan Prasad
9. Regulation of Pesticide Stress on Metabolic Activities of
Plant........................................................................
.......................99
Santwana Tiwari, Anita Singh, and Sheo Mohan Prasad
10. Oxidative Stress and Its Management in Plants During Abiotic
Stress.......................................................................
.........111
P. Faseela, A.K. Sinisha, T.T. Dhanya Thomas, and Jos T. Puthur
11. Plant Genome Response Related to Phenylpropanoid Induction under Abiotic
Stresses...................................................127
Ariel D. Arencibia
12. Metabolic Control of Seed Dormancy and Germination: New Approaches Based
in Seed Shape
Quantification in Desert
Plants.......................................................................
..........................................................................137
Emilio Cervantes, José Javier Martín Gómez, and Ezzeddine Saadaoui
13. Plant Ionomics: An Important Component of Functional
Biology......................................................................
..................147
Anita Mann, Sangeeta Singh, Gurpreet, Ashwani Kumar, Pooja Sujit Kumar, and
Bhumesh Kumar
Section II Role of Major Plant Metabolites During Abiotic Stress Management
14. Role of Glutamate-Derived Amino Acids under Stress Conditions: The Case
of Glutamine and Proline........................157
Marco Biancucci, Roberto Mattioli, Adra Mouellef, Nadia Ykhlef, and Maurizio
Trovato
15. Role of Glycinebetaine and Trehalose as Osmoregulators During Abiotic
Stress Tolerance in Plants.............................171
Mona G. Dawood and Mohamed E. El-Awadi
16. Polyamine Metabolism and Abiotic Stress Tolerance in
Plants.......................................................................
......................191
Rubén Alcázar and Antonio F. Tiburcio
17. Plant Glycine-Rich Proteins and Abiotic Stress
Tolerance....................................................................
.................................203
Juan Francisco Jiménez-Bremont, Maria Azucena Ortega-Amaro, Itzell Eurídice
Hernández-Sánchez, Alma Laura
Rodriguez-Piña, and Israel Maruri-Lopez
18. Compatible Solutes and Abiotic Stress Tolerance in
Plants.......................................................................
............................213
Vinay Kumar, Tushar Khare, Samrin Shaikh, and Shabir H. Wani
19. Protective Role of Indoleamines (Serotonin and Melatonin) During Abiotic
Stress in Plants............................................221
Ramakrishna Akula, Sarvajeet Singh Gill, and G.A. Ravishankar
20. Flavonoid Accumulation as Adaptation Response in Plants during Abiotic
Stresses..........................................................229
Rubal, Ashok Dhawan, and Vinay Kumar
21. The Role of Gamma Aminobutyric Acid (GABA) During Abiotic Stress in
Plants.............................................................239
Paramita Bhattacharjee, Sasanka Chakraborti, Soumi Chakraborty, and Kaninika
Paul
Section III Role of Specialized Proteins During Abiotic Stress Management
22. MicroRNAs: Emerging Roles in Abiotic Stresses and Metabolic
Processes....................................................................
.....251
Susana S. Araújo, Carolina Gomes, Jorge A.P. Pavia, Alma Balestrazzi, and
Anca Macovei
23. Current Understanding of Regulation of GBF3 Under Abiotic and Biotic
Stresses and Its Potential Role in
Combined Stress
Tolerance....................................................................
.............................................................................
.......267
Sandeep Kumar Dixit, Aarti Gupta, and Muthappa Senthil-Kumar
24. microRNAs: Key Modulators of Drought Stress Responses in
Plants.......................................................................
...........273
A. Thilagavathy, Kavya Naik, and V.R. Devaraj
25. Proteomics of Salinity Stress: Opportunities and
Challenges...................................................................
.............................285
Shweta Jha
Section IV Role of Signaling Molecules Under Abiotic Stress Management
26. Signaling Molecules and Their Involvement in Abiotic and Biotic Stress
Response Crosstalk in Plants..........................295
V.R. Devaraj and R.D. Myrene
27. Current Understanding of the Role of Jasmonic Acid During Photoinhibition
in Plants...................................................311
Ruquia Mushtaq, Sarvajeet S. Gill, Shruti Kaushik, Anil K. Singh, Akula
Ramakrishna, and Geetika Sirhindi
28. Current Scenario of NO (S-Nitrosylation) in Cold
Stress.......................................................................
................................331
Yaiphabi Sougrakpam, Priyanka Babuta, and Renu Deswal
29. Physiological Roles of Brassinosteroids in Conferring Temperature and
Salt Stress Tolerance in Plants.......................341
Sirhindi Geetika, Bhardwaj Renu, Kumar Manish, Kumar Sandeep, Dogra Neha,
Sekhon Harpreet,
Kaushik Shruti and Madaan Isha
Section V Biotechnological Applications to Improve the Plant
Metabolic Pathways Towards Better Adaptations
30. Genetic Engineering Approaches for Abiotic Stress Tolerance in Broccoli:
Recent Progress............................................363
Pankaj Kumar, Ajay Kumar Thakur, and Dinesh Kumar Srivastava
31. Impact of Abiotic Stresses on Metabolic Adaptation in Opium Poppy
(Papaver somniferum L.).....................................371
Ankesh Pandey, S. N. Jena, and Sudhir Shukla
32. In Vitro Selection and Genetic Engineering for Abiotic Stress Tolerant
Plants and Underlying Mechanism..................383
Srinath Rao and H. Sandhya
33. Plant-environment Interaction: Influence of Abiotic Stress on Plant
Essential Oil Yield and Quality.............................391
Marine Hussain, Barbi Gogoi, Babita Joshi, Bitupon Borah, Lucy Lalthafamkimi
and B.S. Bhau
34. Differences in Adaptation to Water Stress in Stress Sensitive and
Resistant Varieties of Kabuli and Desi Type
Chickpea.....................................................................
.............................................................................
.....................................403
Nadia Fatnassi, Ralph Horres, Natasa Cerekovic, Angelo Santino, and Palmiro
Poltronieri
Ramakrishna Akula is currently a scientist at Monsanto Breeding Station, Bangalore, India. Dr. Ramakrishna holds a master's degree from Sri Krishna Devaraya University, Anantapur, India. He started his research career in 2005 at the Department of Plant Cell Biotechnology, CFTRI, Mysuru, in the research group of Dr. G.A. Ravishankar. He is a Senior Research Fellow of CSIR, New Delhi. He obtained his Ph.D. in biochemistry from University of Mysore, Mysuru, in the area of development of high frequency somatic embryogenesis and regulation of secondary metabolites in Coffea canephora. He worked extensively on the role of serotonin, melatonin, and calcium-mediated signaling in plants. He has made significant contributions to metabolic engineering of secondary metabolites from plants and abiotic stress in plants. He has worked in the area of tissue culture, in vitro production, and regulation of plant secondary metabolites from food value plants that include natural pigment caffeine, steviosides, anthocyanins, and carotenoids. He is the author of three books, 12 peerreviewed publications, two reviews, and eight chapters in books. His books include Serotonin and Melatonin: Their Functional Role in Plants, Food, Phytomedicine, and Human Health, Metabolic Adaptations in Plants During Abiotic Stress (CRC Press, 2016) and Neurotransmitters in Plants: Perspectives and Applications (CRC Press, 2018). He is a member of the Society for Biotechnologists (India). He is a fellow of the Society for Applied Biotechnology, India (2012), and has received the Global Vegetable Research Excellence Award (2017), three global technology recognition awards, a Rapid Recognition Award, Test Master, Asia Veg R&D quarterly recognitions, and special recognition from the Monsanto company. He attended the Fifth International Symposium on Plant Neurobiology held in 2009 in Florence, Italy. He also attended the Technical Community of Monsanto (TCM) held in 2016, in St. Louis, Missouri.
Dr. Sarvajeet Singh Gill is currently working as assistant professor at the Centre for Biotechnology, Maharshi Dayanand University, Rohtak, Haryana, India. In 2001, Dr. Gill completed an MSc in botany from Aligarh Muslim University, Aligarh, INDAI, with a Gold Medal. Soon after, Dr. Gill started his research career (M.Phil. and PhD, 2001 2008) in plant stress physiology and molecular biology at AMU. Dr. Gill has made significant contributions towards abiotic stress tolerance in crop plants. Dr. Gills research includes abiotic stress tolerance in crop plants, reactive oxygen species signaling and antioxidant machinery, gene expression, helicases, crop improvement, transgenics, nitrogen and sulfur metabolism, and plant fungal symbiotic interactions. Together with Dr. Narendra Tuteja at the International Centre for Genetic Engineering and Biotechnology (ICGEB), New Delhi, he worked on plant helicases for abiotic stress tolerance. He further explored the mechanism of stress tolerance by PDH45 in tobacco and rice (Plant Mol Biol 82(12):122, 2013, and PLoS One 9(5):e98287, 2014). Dr. Gill discovered a novel function of plant MCM6 in salinity stress tolerance that will help to improve crop production at sub-optimal conditions (Plant Mol Biol 76(2011):1934, 2014). Herbicide and salinity stress tolerance (PDH45 + EPSPS) in plants has also been explored by Dr. Gill (Front. Plant Sci. 8:364, 2017). He helped to develop salinity-tolerant tobacco and rice plants, without affecting the overall yield. This research uncovers new pathways to plant abiotic stress tolerance and indicates the potential for improving crop production at sub-optimal conditions. A recipient of the INDIA Research Excellence & Citation Award 2017 from Clarivate Analytics (Web of Science), Sarvajeet Gill has edited several books with Springer, Wiley, Elsevier, CABI, and others, and has a number of research papers, review articles, and book chapters to his name.
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