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E-grāmata: Senescence Signalling and Control in Plants

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Edited by (Amity Institute of Microbial Technology, Noida, India; Visiting Scientist at International Centre for Genetic Engi), Edited by (Senior Assistant Professor, Pharmaceutical Biotechnology, Amity Institute of Pharmacy, Amity University, Noida, India)
  • Formāts: EPUB+DRM
  • Izdošanas datums: 29-Nov-2018
  • Izdevniecība: Academic Press Inc
  • Valoda: eng
  • ISBN-13: 9780128131886
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Senescence Signalling and Control in PlantsPalielināt
  • Formāts: EPUB+DRM
  • Izdošanas datums: 29-Nov-2018
  • Izdevniecība: Academic Press Inc
  • Valoda: eng
  • ISBN-13: 9780128131886
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Senescence Signalling and Control in Plants discusses the studies showing the importance of hormone action on developmental senescence. It shows the involvement of various signaling components (like EIN2, LOX2) and transcription factors (like oresara1 or ORE1) in controlling hormonal activity during senescence. Further, the involvement of various micro RNAs (miR164, miR319) in regulating leaf senescence are discussed. Through this book, the authors throw light on all the reverse and forward genetic approaches to reveal the role of various other phytohormones regulating plant senescence and the molecular mechanisms involved.

Chapters on relevant topics are contributed by experts working in the area, making this a comprehensive treatise designed to provide an in-depth analysis on the subject matter.

  • Throws light on the involvement of hormones (other than the well- known hormones cytokine and ethylene) in plant senescence
  • Shows the underlying mechanisms on the hormonal actions during senescence
  • Exhibits the involvement of microRNAs during this important plant developmental process
Contributors ix
1 The Physiology and Molecular Biology of Stress-Induced Senescence
Md. Mahadi Hasan
Iffat-Ara Sharmeen
Khalid Rehman Hakeem
Hesham F. Alharby
Abdulrahaman S. Hajar
1 Introduction
1(2)
2 Senescence-Associated Genes and Abiotic Stress
3(3)
3 Salt Stress and Leaf Senescence
6(1)
4 Extreme Temperature and Leaf Senescence
6(1)
5 Low Temperature and Leaf Senescence
7(1)
6 Heavy Metal and Leaf Senescence
7(1)
7 Ultraviolet Radiation and Leaf Senescence
8(1)
8 Ozone and Leaf Senescence
8(1)
9 Conclusions and Future Research
9(1)
References
10(5)
2 Abiotic Stress and Plant Senescence
Saiema Rasool
Bilal Ahmad Mir
Muneeb U. Rehman
Insha Amin
Manzoor Ur Rahman Mir
Sheikh Bilal Ahmad
1 Introduction
15(1)
2 Senescence in Plant Cells (Programmed Cell Death)
16(1)
3 ROS and Senescence
16(3)
4 Abiotic Stress--Induced Chloroplast Degradation During Senescence
19(1)
5 UV Radiation--Induced Stress
19(1)
6 Drought Stress---Soil Water Scarcity
20(2)
7 Strategies to Control Abiotic Stress--Induced Plant Senescence
22(1)
8 Conclusion
23(1)
References
23(6)
3 Plant Leaf Senescence: Integrating Multiple Environmental and Internal Cues
Samir Sharma
Sudhir K. Agarwal
1 Introduction
29(1)
2 Characteristics of Leaf Senescence
30(1)
3 Changes in Canopy Structure Induces an Inclination to Senesce: The Nitrogen Connection
31(1)
4 Light Deprivation: The Central Regulator of Leaf Senescence
32(3)
5 Reactive Oxygen in Leaf Senescence: The Mitochondrial Conundrum
35(2)
6 Conclusion
37(1)
References
38(3)
4 Signal Transduction in Leaf Senescence: An Overview
Ishpaq Majid
Nazia Abbas
1 Introduction
41(1)
2 Environmental Factors Regulating Leaf Senescence
42(1)
3 Hormonal Regulation of Leaf Senescence
43(6)
4 Transcriptional Regulation of Leaf Senescence
49(3)
5 Conclusion and Perspectives
52(1)
Acknowledgments
53(1)
References
53(6)
Further Reading
59(2)
5 Regulation of Leaf Senescence by Macromolecule Degradation and Hormones
Shabnam Akhtar
Altaf Ahmali
Shipra R. Jha
Javed Ahmad
1 Introduction
61(1)
2 Beginning of Leaf Senescence
62(1)
3 Genetic Expression During Leaf Senescence
63(7)
4 Regulation of Leaf Senescence
70(17)
5 Genes Involved in Ocher Degradative Physiological Processes
87(1)
6 Conclusion and Future Perspectives
87(1)
References
88(9)
Further Reading
97(2)
6 The Role of Growth Regulators in Senescence
Imran Haider Shamsi
Tichaona Sagonda
Xin Zhang
Geraldzvobgo
Heren Issaka Joan
1 Introduction
99(1)
2 Plant Growth Regulators
100(1)
3 PGRs in Senescence
100(6)
4 PGR Cross-Talk
106(2)
5 Conclusion
108(1)
Acknowledgments
108(1)
References
108(2)
Further Reading
110(1)
7 Jasmonic Acid (JA)-Mediated Signaling in Leaf Senescence
Abidullah
Adnan Akbar
Xiyan Yang
1 Introduction
111(1)
2 Signal Regulation in Leaf Senescence
112(4)
3 JA-Induced Leaf Senescence
116(4)
4 Conclusion
120(1)
References
120(3)
Further Reading
123(2)
8 Polyamine as Signaling Molecules and Leaf Senescence
Autar K. Mattoo
Ewa Sobieszczuk-Nowicka
1 Introduction
125(1)
2 Polyamines and Senescence
126(6)
3 Perspectives: Nitrous Oxide (NO), Polyamines (PAs), and Hydrogen Peroxide (H2O2)---A Signaling Triad That Regulates Leaf Senescence?
132(2)
References
134(5)
9 Oxidative Stress and Leaf Senescence: Important Insights
Vinay Kumar
Tushar Khare
Amrita Srivastav
Challa Surekha
Varsha Shriram
Shabir H. Wani
1 Leaf Senescence: An Important Developmental Process in Plants
139(1)
2 Progression and Regulation of Leaf Senescence
140(7)
3 Correlation Between Oxidative Stress and Leaf Senescence
147(3)
4 Expression Levels of Senescence-Related Genes in the Oxidative Environment
150(3)
5 Targeting Leaf Senescence as a Potent Strategy for Crop Improvement Against Abiotic Oxidative Stress
153(1)
6 Conclusion
154(1)
Acknowledgments
155(1)
References
155(7)
Further Reading
162(3)
10 Proteolytic Processes During Leaf Senescence
Shaista Qadir
Iram Ayub
Maryam Sarwat
Riffat John
1 Introduction
165(2)
2 Experimental Material for the Study of Leaf Senescence
167(10)
3 Conclusion and Future Aspects
177(1)
References
178(7)
Further Reading
185(2)
11 Role of Histones During Leaf Senescence
Bhubaneswar Pradhan
Krishna Kumar Jangid
Maryam Sarwat
Sujit Kumar Bishi
1 Introduction
187(1)
2 Physiological and Biochemical Events During Leaf Senescence
188(1)
3 Molecular Genetics of Leaf Senescence
189(1)
4 Role of Histones in Leaf Senescence
190(4)
5 Conclusion and Future Prospects
194(1)
Acknowledgment
194(1)
References
194(5)
12 Receptor-Like Kinases Control the Development, Stress Response, and Senescence in Plants
Nishat Passricha
Shabnam K. Saifi
Rakshita Singh
Bushpa Kharb
Narendra Tuteja
1 Introduction
199(1)
2 RLKs in Plant Development
200(1)
3 RLKs in Senescence
201(1)
4 RLKs in Hormone Signaling
202(1)
5 RLKs in Stress Responses
202(1)
6 Abiotic Stresses
203(2)
7 Biotic Stresses
205(1)
8 Concluding Remarks
206(1)
References
207(4)
13 Flower Senescence: Present Status and Future Aspects
Maryam Sarwat
Narendra Tuteja
1 Introduction
211(2)
2 Events Associated With Senescence
213(5)
3 Interactions Between Ethylene and Other Hormones During Flower Senescence
218(3)
4 Conclusion and Future Prospects
221(1)
References
221(6)
14 Nutrient Remobilization During Senescence
Mukhtar Ahmad Bhat
Helal
Ahmad Lone
Syed Sana Mehraj
1 Introduction
227(1)
2 Macro and Micronutrient Remobilization During Senescence
228(1)
3 Senescence and Sugars
229(1)
4 Senescence and Sulfur
230(1)
5 Senescence and Potassium
230(1)
6 Senescence and Nitrogen
230(1)
7 Senescence and Phosphorus
231(1)
8 Phytohormone and Senescence
232(1)
9 Reactive Oxygen Species and Senescence
233(1)
10 Conclusion
234(1)
References
234(3)
Further Reading
237(3)
15 Autophagy and Senescence
Wei Lan
Ying Miao
1 The Mechanism of Autophagy
240(4)
2 Autophagy and Senescence
244(5)
3 Discussion
249(1)
4 Conclusion
250(1)
References
250(5)
16 Plant Senescence and Organ Abscission
255(1)
Mohdguleishan
Ajmat Jahan
Tariq Ahmad Bhat
Danish Sahab
1 Introduction
255(2)
2 Mechanism of Senescence and Abscission
257(4)
3 Role of Hormones in Senescence and Abscission
261(4)
4 Conclusion
265(1)
References
266(6)
Further Reading
272(1)
17 Senescence-Associated Markers
Jyoti Bala
Anupam J. Das
Hoshang Unwalla
1 Introduction
273(1)
2 Characteristics of Senescence
274(1)
3 Senescence-Associated Markers in Plants
275(3)
4 Summary
278(1)
Acknowledgments
279(1)
Conflict of Interest
280(1)
References
280(3)
18 Plant Senescence and Agriculture
Pranjal Yadava
Alla Singh
Krishan Kumar
Sapna
Ishwar Singh
1 Introduction
283(1)
2 Monocarpic Senescence Versus Polycarpic Senescence
283(1)
3 Orchestrated Biological Events During Transition to Flowering
284(1)
4 Leaf Senescence in Plants
285(1)
5 Senescence Triggers
285(1)
6 Biological Changes Accompanying Leaf Senescence
286(1)
7 Molecular Mechanisms Operating During Senescence
287(1)
8 The Impact of Senescence on Source-Sink Relationship and Crop Yield
288(1)
9 Utilization of the Stay-Green Trait in Crop Improvement
289(2)
10 Senescence and Postharvest Quality of Produce
291(1)
11 Plant Genetic Engineering for Manipulation of Senescence
291(6)
12 Conclusion
297(1)
Acknowledgments
297(1)
Conflict of Interest
297(1)
References
298(4)
Further Reading
302(1)
Index 303
Dr. Maryam Sarwat is an Indian Citizen, working as an Associate Professor in the Amity Institute of Pharmacy, Amity University, Noida. She has obtained her Ph. D. in 2007 and completed postdoctoral research at ICGEB, New Delhi. She has received several research grants from various R & D agencies such as DST, DBT, CCRUM and SERB in India. She has presented her findings in scientific conferences in various countries like Germany, Czech Republic and France etc. Dr. Sarwat has mentored six PhD and fifteen Masters students. She has more than 55 international publications in reputed journals and three patents to her credit. She is the recipient of the prestigious Scientist of the Year Award” in 2015. Dr. Sarwat has published two volumes of Stress Signaling in Plants, Genomics and Proteomics Perspective” with Springer Nature in 2013 and 2017. She has also authored two books with Elsevier entitled Senescence Signaling and Control in Plants in 2018 and Saffron: The Age-Old Panacea in a New Light in the early 2020. She has also published the title Environment and Human Health through King Abdul Aziz University Press in 2020. Her two volumes on Ethnic Knowledge on Biodiversity, Nutrition and Health Security are due for publication by Taylor and Francis in 2021. She has served various international journals as reviewer An elected fellow of numerous national and international academies, Dr. Narendra Tuteja is currently Professor and head at Amity Institute of Microbial Technology, NOIDA, India, and visiting Scientist at International Centre for Genetic Engineering & Biotechnology (ICGEB), New Delhi, India. He has made significant contributions to crop improvement under adverse conditions, reporting the first helicase from plant and human cells and demonstrating new roles of Ku autoantigen, nucleolin and eIF4A as DNA helicases. Furthermore, he discovered novel functions of helicases, G-proteins, CBL-CIPK and LecRLK in plant stress tolerance, and PLC and MAP-kinase as effectors for G and G G-proteins. Narendra Tuteja also reported several high salinity stress tolerant genes from plants and fungi and developed salt/drought tolerant plants.
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