Investigate the physiological, biochemical, and productivity aspects of crops to cold stress
الموضوعات :
Roghiyeh Farzi Aminabad
1
,
Safar Nasrollahzadeh
2
1 - Department of Plant Ecophysiology, Faculty of Agriculture, University of Tabriz, Tabriz, Iran
2 - Department of Plant Ecophysiology, Faculty of Agriculture, University of Tabriz, Tabriz, Iran
الکلمات المفتاحية: Cold, Chilling, Freezing, ICE1, COR Genes,
ملخص المقالة :
Cold stress is one of the environmental stresses that affects the growth, development, and productivity of crops in various climates. Understanding the physiological and biochemical mechanisms by which plants respond to this stress can improve their growth and development. Cold stress can be categorized into two types: freezing stress and chilling stress. Freezing stress occurs when the temperature drops below 0 °C, while chilling stress occurs when the temperature ranges between 0 and 15 °C. Cold stress leads to the destruction or alteration of membrane proteins, causing a loss of membrane fluidity. This stress also increases the production of oxygen free radicals (ROS), which attack and destroy cell membranes. If cold stress persists, it can ultimately result in plant death. The ICE1-CBF-COR transcription cascade serves as a major signaling pathway activated in response to cold stress in plants. This cascade involves the induction of CBF genes, which encode transcription factors that bind to the promoter of COR genes, initiating their transcription. Enzymes such as SOD, APX, CAT, and GR exhibit increased activity in response to low temperatures. Additionally, the accumulation of MDA can serve as an indicator of oxidative stress sensitivity and cold tolerance. Cold stress has detrimental effects on crop yield formation. It initially impairs the reproductive phase of plants, ultimately leading to reduced final yields.
المصادر:
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Ding, Y., Y. Shi and S. Yang. 2019. Advances and challenges in uncovering cold tolerance regulatory mechanisms in plants. New Phytologist, 222: 1690-1704.
Deng, X., J. Wang and Y. Li, 2018. Comparative transcriptome analysis reveals phytohormone signaling, heat shock module and ROS scavenger mediate the cold tolerance of rubber tree. Scientific Reports, 8: 4931.
Farooq, M., M. Hussain, A. Nawaz, D. J. Lee, S. S. Alghamdi and KH. M Siddique, 2017. Seed priming improves chilling tolerance in chickpea by modulating germination metabolism, trehalose accumulation and carbon assimilation. Plant Physiology Biochemistry, 111: 274-283.
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Hajihashemi, S., F. Noedoost, J. M. C. Geuns, I. Djalovic and KH. M. Siddique, 2018. Effect of Cold Stress on Photosynthetic Traits, Carbohydrates, Morphology, and Anatomy in Nine Cultivars of Stevia rebaudiana. Frontiers in Plant Science, 9: 1430.
Hassan, M. A., C. Xiang, M. Farooq, N. Muhammad, Z. Yan, X. Hui, K. Yuanyuan, A. K. Bruno, Z. Lele and L. Jincai, 2021. Cold stress in wheat: plant acclimation responses and management strategies. Frontiers in Plant Science 12: 676884.
Han, D., J. Han, G. Yang, S. Wang, T. Xu and W. Li, 2020. An ERF transcription factor gene from (Malus baccata L.) Borkh, MbERF11, affects cold and salt stress tolerance in Arabidopsis. Forests, 11: 514.
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Heidarvand, L and R. Maali-Amiri 2013. Physio-biochemical and proteome analysis of chickpea in early phases of cold stress. Journal of Plant Physiology, 170: 459-469.
Huang, X., H. Shi, Z. Hu, A. Liu, E. Amombo, L. Chen and J. Fu, 2017. ABA is involved in regulation of cold stress response in bermudagrass. Frontiers in Plant Science, 8: 1613.
Hu, Y. R., Y. J. Jiang, X. Han, H. P. Wang, J. J. Pan and D. Q. Yu, 2017. Jasmonate regulates leaf senescence and tolerance to cold stress: Crosstalk with other phytohormones. Journal of Experimental Botany, 68: 13611369.
Hu, Y., L. Jiang, F. Wang and D. Yu, 2013. Jasmonate regulates the inducer of cbf expression-C-repeat binding factor/DRE binding factor1 cascade and freezing tolerance in Arabidopsis. The Plant Cell, 25: 2907-2924.
Hurry, V. M and N. P. Huner, 1992. Effect of cold hardening on sensitivity of winter and spring wheat leaves to short-term photoinhibition and recovery of photosynthesis. Plant Physiology, 100: 1283-1290.
Hussain, H. A., S. Hussain, A. Khaliq, U. Ashraf, S. A. Anjum, S. Men and L. Wang, 2018.Chilling and drought stresses in crop plants: implications, cross talk, and potential management opportunities. Frontiers in Plant Science, 9: 393.
Jan, N., U. Majeed, K. I. Andrabi and R. John, 2018. Cold stress modulates osmolytes and antioxidant system in Calendula officinalis. Acta physiologiae plantarum. 40: 1-16.
Jarzabek, M., P. M. Pukacki and K. Nuc, 2009. Cold-regulated proteins with potent antifreeze and cryoprotective activities in spruces (Picea spp.). Cryobiology, 58: 268-274.
Kidokoro, S., K. Hayashi, H. Haraguchi, T. Ishikawa, F. Soma, I. Konoura, S. Toda, J. Mizoi, T. Suzuki and K. Yamaguchi-Shinozaki, 2021. Posttranslational regulation of multiple clock-related transcription factors triggers cold-inducible gene expression in Arabidopsis. proceedings of the national academy of sciences, india section b. Biological Sciences, 118: e2021048118
Kosova, K., I. T. Prasil and P. Vitamvas, 2008. The relationship between vernalization and photo periodically-regulated genes and the development of frost tolerance in wheat and barley. Biologia Plantarum, 52: 601-615.
Krupa, Z., G. Oquist and P. Gustafsson. 1990. Photoinhibition and Recovery of Photosynthesis in psbA Gene Inactivated Strains of cyanobacterium Anacystis nidulans. Plant Physiology, 93: 1-6.
Lantzouni, O., A. Alkofer, P. Falter-Braun and C. Schwechheimer, 2020. Growth-regulating factors interact with DELLAs and regulate growth in cold stress. The Plant Cell, 32: 1018-1034.
Lei, Y. A. N., T. Shah, Y. Cheng, L. Ü. Yan, X. K. Zhang and X. L. Zou, 2019. Physiological and molecular responses to cold stress in rapeseed (Brassica napus L.). Journal of Integrative Agriculture, 18: 2742-2752.
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