"Ethylene in Plant Biology presents ethylene research from leading laboratories around the globe to allow readers to gain strong foundational coverage of the topic and aid in further ethylene research as it pertains to plant biology. The work details theoverall role of ethylene in plant biology, a gaseous plant hormone that has emerged as an important signaling molecule which regulates several steps of a plant's life cycle, covering both general ideas as well as more specific and technical knowledge. The ideas covered in the work range from discovery of ethylene, to its wide roles in plant growth and development, all the way to niche topics such as stress acclimation"--
ETHYLENE IN PLANT BIOLOGY Comprehensive resource detailing the role of ethylene in plant development regulation, gene regulation, root development, stress tolerance, and more
Ethylene in Plant Biology presents ethylene research from leading laboratories around the globe to allow readers to gain strong foundational coverage of the topic and aid in further ethylene research as it pertains to plant biology. The work covers general ideas as well as more specific and technical knowledge, detailing the overall role of ethylene in plant biology as a gaseous plant hormone that has emerged as an important signaling molecule which regulates several steps of a plants life cycle. The ideas covered in the work range from discovery of ethylene, to its wide roles in plant growth and development, all the way to niche topics such as stress acclimation.
Written by highly qualified authors in fields directly related to plant biology and research, the work is divided into 20 chapters, with each chapter covering a specific facet of ethylene or the interaction between ethylene and plant health. Topics discussed in the text include:
- Our current understanding of ethylene and fruit ripening, plus the role of ethylene in flower and fruit development
- Ethylene implications in root development and crosstalk of ethylene with other phytohormones in plant development
- Ethylene as a multitasking regulator of abscission processes and powerful coordinator of drought responses
- Mechanisms for ethylene synthesis and homeostasis in plants, along with ethylene and phytohormone crosstalk in plant defense
- Ethylene and metabolic reprogramming under abiotic stresses, as well as ethylenes applications in crop improvement
For biologists, scientists, researchers, and policy makers in the agriculture and pharmaceutical industries, Ethylene in Plant Biology is a key resource to understand the state of the art in the field and establish a foundation of knowledge that can power future research efforts and practical applications.
List of Contributors v
Preface ix
1 Ethylene Implication in Root Development 1
Aditi Gupta, Anshu Rastogi, and Manjul Singh v
2 Crosstalk of Ethylene and Other Phytohormones in the Regulation of Plant
Development 17
Savita Bhardwaj, Dhriti Sharma, Sadaf Jan, Rattandeep Singh, Renu Bhardwaj,
and Dhriti Kapoor
3 Ethylene and Regulation of Metabolites in Plants 32
Savita Bhardwaj, Tunisha Verma, and Dhriti Kapoor
4 Ethylene as a Multitasking Regulator of Abscission Processes 49
Agata Kuko, Timothy J. Tranbarger, Juan D. Alché, and Emilia Wilmowicz
5 Ethylene: A Powerful Coordinator of Drought Responses 82
Emilia Wilmowicz, Agata Kuko, Sebastian Burchardt, and Jacek Karwaszewski
6 Current Understanding of Ethylene and Fruit Ripening 109
Shubhra Gupta, Kapil Gupta, Jasminkumar Kheni, and Jogeswar Panigrahi
Copyrighted Material
7 Ethylene and ROS Crosstalk in Plant Developmental Processes 125
Kumar Chandra- kuntal
8 Role of Ethylene in Flower and Fruit Development 178
Cecilia Martķnez, Alicia Garcķa, and Manuel Jamilena
9 Ethylene and Nutrient Regulation in Plants 220
Badar Jahan, Zebus Sehar, Harsha Gautam, Mehar Fatma, Noushina Iqbal, Asim
Masood, and Nafees A. Khan
10 Plant Metabolism Adjustment in Exogenously Applied Ethylene under Stress
246
Niharika, N.B. Singh, Ajey Singh, and Shubhra Khare
11 Role of ET and ROS in Salt Homeostasis and Salinity Stress Tolerance and
Transgenic Approaches to Making Salt- Tolerant Crops 259
Neeraj Kumar Dubey, Kapil Gupta, Surendra Pratap Singh, Jogeswar Panigrahi ,
and Satendra Pal Singh
12 Ethylene and Phytohormone Crosstalk in Plant Defense Against Abiotic
Stress 277
Nimisha Amist and N.B. Singh
13 Mechanism for Ethylene Synthesis and Homeostasis in Plants: Current
Updates 291
Rachana Tripathi, Nisha Agrawal, and Meeta Jain
14 Ethylene and Nitric Oxide Under Salt Stress: Exploring Regulatory
Interactions 312
Noushina Iqbal, Peer Saffeullah, and Shahid Umar
15 Ethylene and Metabolic Reprogramming under Abiotic Stresses 345
Nisha Agrawal, Rachana Tripathi, and Meeta Jain
16 Regulation of Thermotolerance Stress in Crops by Plant Growth- Promoting
Rhizobacteria Through Ethylene Homeostasis 363
Priyanka Gogoi, Parishmita Gogoi, Archana Yadav, and Ratul Saikia
17 Ethylene: Signaling, Transgenics, and Applications in Crop Improvement
374
Pragati Kumari, Rahul Thakur, Arvind Gupta, Vinay Kumar, Archana Thakur, and
Saurabh Yadav
18 Role of Ethylene in Combating Biotic Stress 388
Shivam Jasrotia and Raman Jasrotia
19 Ethylene and Nitric Oxide Crosstalk in Plants under Abiotic Stress 398
Juhie Joshi- Paneri, Kanchan Jumrani, Sunita Kataria, Anita Dubey, and Meeta
Jain
20 Polyamine Metabolism and Ethylene Signaling in Plants 420
Ekhlaque A. Khan, Zahra Souri, and Vķctor Garcķa- Gaytįn
Index 437
Samiksha Singh, Laboratory of Herbal Pesticides, Banaras Hindu University, Varanasi, India.
Tajammul Husain, Department of Botany, University of Allahabad, Prayagraj, India.
Vijay Pratap Singh, Department of Botany, C.M.P. Degree College, University of Allahabad, Prayagraj, India.
Durgesh Kumar Tripathi, Crop Nanobiology and Molecular Stress Physiology Laboratory, Amity Institute of Organic Agriculture, Amity University Uttar Pradesh, India.
Sheo Mohan Prasad, Department of Botany, University of Allahabad, Prayagraj, India.
Nawal Kishore Dubey, Laboratory of Herbal Pesticides, Banaras Hindu University, Varanasi, India.
