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http://dx.doi.org/10.7740/kjcs.2020.65.1.022

Impact of Heat Stress on Pollen Fertility Rate at the Flowering Stage in Korean Rice (Oryza sativa L.) Cultivars  

Thuy, Tran Loc (Cuu Long Delta Rice Research Institute)
Lee, Chung-Kuen (Crop Production & Physiology Division, Nation Institute of Crop Science)
Jeong, Jae-Hyeok (Crop Production & Physiology Division, Nation Institute of Crop Science)
Lee, Hyeon-Suk (Crop Production & Physiology Division, Nation Institute of Crop Science)
Yang, Seo-Young (Crop Production & Physiology Division, Nation Institute of Crop Science)
Im, Yeon-Hwa (Crop Production & Physiology Division, Nation Institute of Crop Science)
Hwang, Woon-Ha (Crop Production & Physiology Division, Nation Institute of Crop Science)
Publication Information
KOREAN JOURNAL OF CROP SCIENCE / v.65, no.1, 2020 , pp. 22-29 More about this Journal
Abstract
Rice is very sensitive to high temperatures during the reproductive stage, particularly during the flowering and anthesis periods. To determine how high temperatures result in sterility during the flowering period in Korean rice cultivars, groups of 11 cultivars were subjected to different temperature regimes (24, 28, 30, and 33℃) during the flowering stage using sunlit phytotrons. At an average of 33℃, all 11 rice cultivars reached anthesis earlier than at the other temperatures. Microscopy analyses revealed significant differences in pollen germination and pollen viability in cultivars grown at 33℃ compared to those cultured at lower temperatures. At 33℃, the cultivars had significantly lower fertility rates (47% reduction) than cultivars grown at 24℃. These findings are important as rice pollination and fertility depend on the pollen viability and germination. The present study shows that rice fertility is negatively affected by excessively high temperatures.
Keywords
high temperature; pollen germination; pollen viability and spikelet fertility;
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1 Shi, C. L., Z. Q. Luo, M. Jiang, Y. L. Shi, Y. X. Li, S. L. Xuan, Y. Liu, S. B. Yang, and G. K. Yu. 2017. A quantitative analysis of high temperature effects during meiosis stage on rice grain number per panicle. Chinese Journal of Rice Science 31(6) : 658-664.
2 Siddik, M. A., J. Zhang, J. Chen, Q. Haoyu, Y. Jian, A. K. Raheem, A. Deng, Z. Song, C. Zhen, and W. Zhang. 2019. Response of indica rice yield and quality to extreme high and low temperatures during the reproductive period. European Journal of Agronomy 106 : 30-38.   DOI
3 Tan, L. H., T. Y. Zan, C. F. Ren, and W. Fang. 1985. Studies on high temperature injury on hybrid rice at flowering time and the strategy to avoid high temperature damage. Acta Agronomica Sinica 11(2) : 103-108.
4 Tian, X., T. Matsui, S. Li, M. Yoshimoto, K. Kobayashi, and T. Hasegawa. 2010. Heat induced floret sterility of hybrid rice (Oryza sativa L.) cultivars under humid and low wind condition in the field of Jianghan Basin, China. Plant Production Science 13 : 243-251.   DOI
5 Wang, Y. L., Y. P. Zhang, D. F. Zhu, J. Xiang, H. Wu, H. Z. Chen, and Y. K. Zhan. 2016. Effect of heat stress on spikelet degeneration and grain filling at panicle initiation period of rice. Acta Agronomica Sinica 42(9) : 1402-1410.   DOI
6 Wang, Y., L. Wang, J. Zhou, S. Hu, H. Chen, J. Xiang, Y. Zhang, Y. Zen, Q. Shi, D. Zhu, and Y. Zhang. 2019. Research progress on heat stress of rice at flowering stage. Rice Science 26(1) : 1-10.   DOI
7 Yang, Z., Z. Zhang, T. Zhang, S. Fahad, K. Cui, L. Nie, S. Peng, and J. Huang. 2017. The effect of season-long temperature increases on rice cultivars grown in the central and southern regions of china. Frontiers Plant Science 8 : 1908.   DOI
8 Yoshida, S., T. Satake, and D. Mackile. 1981. High temperature stress. In: IRRI Research Paper Series 67 : 1-5.
9 Coast, O., R. H. Ellis, A. J. Murdoch, C. Q. Uinones, and S. V. K. Jagadish. 2015. High night temperature induces contrasting response for spikelet fertility, spikelet tissue temperature, flowering characteristic and grain quality in rice. Functional Plant Biology 42 : 149-161.   DOI
10 Aghamolki, M. T. K., M. K. Yusop, F. C. Oad, H. Zakikhani, H. Z. Jaafar, S. Kharidad, and M. H. Mohamed. 2014. Heat stress effects on yield parameters of selected rice cultivars at reproductive growth stage. Journal of Food and Environment 12(2) : 741-746.
11 Das, S., P. Krishnan, M. Nayak, and B. Ramakrishnam. 2014. High temperature stress effects on pollens of rice (Oryza sativa L.) genotypes. Environmental and Experimental Botany 101 : 36-46.   DOI
12 FAO. 2019. Agriculture and climate change, challenges and opportunities at the global and local level collaboration on climate smart agriculture. Rome, Italy.
13 Jagadish, S. V. K., R. Muthurajan, R. Oane, T. R. Wheeler, S. Heuer, J. Bennett, and P. Q. Craufurd. 2010. Physiological and proteomic approaches to address heat tolerance during anthesis in rice (Oryza sativa L.). Journal of Experimental Botany 61 : 143-156.   DOI
14 Fu, G., B. Feng, C. Zhang, Y. Yang, X. Yang, T. Chen, X. Zhao, X. Zhang, Q. Jin, and L. Tao. 2016. Heat stress is more damaging to superior spikelets than inferiors of rice (Oryza sativa L.) due to their different organ temperatures. Frontiers in Plant Science 7 : 1637. doi: 10.3389/fpls.2016.01637
15 IPCC. 2014. AR5 Climate change 2014: Impacts, adaption, and vulnerability. Cambridge University Press, New York.
16 Ishimaru, T., H. Hirabayashi, M. Ida, T. Takai, Y. A. San-oh, S. Yoshinaga, I. Ando, T. Ogawa, and M. Kondo. 2010. A genetic resource for early morning flowering trait of mild rice Oryza offficunalis to mitigate high temperature induced spikelet sterility at anthesis. Annals of Botany 106 : 515-520.   DOI
17 Jung, H. S., Y. G. Choi, J. H. Oh, and G. H. Kim. 2002. Recent trends in temperature and precipitation over South Korea. International Journal Climatology 22 : 1327-1337.   DOI
18 Kakani, V. G., K. R. Reddy, S. Koti, T. P. Wallace, P. V. V. Prasad, V. R. Reddy, and O. Zhao. 2005. Differences in invitro pollen germination and pollen tube growth of cotton cultivars in response to high temperature. Annals of Botany 96(1) : 56-67.
19 Kim, M. K., D. K. Lee, S. T. Lee, Y. D. Hong, C. K. Song, and J. A. Yu. 2010. Korean climate change assessment report 2010. National Institute of Environmental Research, Korea.
20 Krishnan, P., B. Ramakrishnan, K. R. Reddy and, V. R. Reddy. 2011. High-temperature effect on rice growth, yield and grain quality. Advance in Agronomy 111 : 87-206.   DOI
21 Met Office. 2011. Climate: Observations, projections and impacts: South Korea. Exeter, UK.
22 Kumar, N., A. Shukla, S. C. Shankhdar, and D. Shankhdar. 2015. Impact of terminal heat stress on pollen viability and yield attributes of rice (Oryza sativa L.). Cereal Research Communication 43 : 616-626.   DOI
23 Lobell, D. B., W. Schlenker, and R. J. Costa. 2011. Climate trends and global crop production since 1980. Science 333 : 616-620.   DOI
24 Matsui, T., K. Omasa, and T. Horie. 2000. High temperature at flowering inhibit swelling of pollen grains, a driving force for thecae dehiscence in rice (Oryza sativa L.). Plant Science Production 3 : 430-434.   DOI
25 Osada, A., V. Sasiprada, M. Rahong, S. dhammanuvong, and M. Chakrabandha. 1973. Abnormal occurrence of empty grain of indica rice plant in the dry, hot season in Thailand. Proceeding of the Crop Society of Japan 42 : 103-109.   DOI
26 Prasad, P. V. V., K. J. Bootee, J. E. Sheedy, and J. M. Thomas. 2006. Species, ecotype and cultivar difference in spikelet fertility and harvest index of rice response to high temperature stress. Field Crops Research 95 : 398-411.   DOI
27 Satake, T. and S. Yoshida. 1978. High temperature induced sterility in indica rice at flowering. Japanese Journal of Crop Science 47 : 6-17.   DOI
28 Shad, F., Z. I. Muhammad, K. Abdul, D. Ihsanullah, S. Shah, A. Saled, N. Wajid, A. Muhammad, A. K. Imtiaz, W. Chao, W. Depen, and H. Jianliang. 2018. Consequence of high temperature under changing climate optima for rice pollen characteristics concepts and perspectives. Archives of Agronomy and Soil Science 64(11) : 1473-1488.   DOI