Progress on Physiological Mechanisms of Rice Spikelet Degeneration at Different Panicle Positions Caused by Abiotic Stress

Progress on Physiological Mechanisms of Rice Spikelet Degeneration at Different Panicle Positions Caused by Abiotic Stress

Rice yield is heavily reliant on the number of spikelets per panicle, a factor determined by the processes of spikelet differentiation and degeneration. In rice cultivars with large panicles, spikelet degeneration negates the advantages of large panicle and constrains yield potential. Environmental...

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Bibliographic Details
Main Authors: Wang Jingqing, Wang Yaliang, Chen Yulin, Chen Huizhe, Xiang Jing, Zhang Yikai, Wang Zhigang, Zhang Yuping
Format: Article
Language:English
Published: Elsevier 2025-03-01
Series:Rice Science
Subjects:
Oryza sativa
spikelet degeneration characteristic
physiological mechanism
cultivation alleviation approach
Online Access:http://www.sciencedirect.com/science/article/pii/S1672630824000842
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Summary:Rice yield is heavily reliant on the number of spikelets per panicle, a factor determined by the processes of spikelet differentiation and degeneration. In rice cultivars with large panicles, spikelet degeneration negates the advantages of large panicle and constrains yield potential. Environmental stress-induced metabolic disorders in plants aggravate spikelet degeneration, with the sensitive period for this process commencing approximately 15‒20 d before panicle heading. Notable positional variations occur within the panicle, with significantly higher spikelet degeneration rates at the basal than at the upper positions. An imbalance of carbon and nitrogen metabolism represents the primary physiological basis for aggravated spikelet degeneration under abiotic stress. Impaired carbon and nitrogen metabolism leads to disordered energy metabolism and disrupted respiratory electron transport, which accelerates the apoptosis of young spikelets through excessive reactive oxygen species accumulation. Sucrose serves as the main carbohydrate source for spikelet development, demonstrating an apical dominance pattern that favors spikelet formation. However, under abiotic stress, the inhibition of sucrose decomposition, rather than sucrose transport impairment, predominantly contributes to aggravated spikelet degeneration at the basal panicle positions. Brassinolide and auxin have a significant relationship with spikelet formation, potentially mediating apical dominance. Specifically, brassinolide enhances sucrose accumulation and utilization, thereby alleviating spikelet degeneration. At present, the mechanisms underlying rice spikelet degeneration have not been fully revealed, and the joint effects of hormones, carbohydrates, and carbon and nitrogen metabolism on this process require further investigation. To reduce the spikelet degeneration, the strategic application of water and fertilizer to establish a stable rice population can enhance the rice plants’ resilience to abiotic stress. An effective approach to reducing spikelet degeneration is to increase the dry matter occupancy of each spikelet during the panicle initiation period.
ISSN:1672-6308

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