[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.7740/kjcs.2018.63.2.112

Ripening Characteristics and Antioxidant Enzyme Activity of Ilmi under Heat Stress Condition

Hwang, Woon-Ha (National Institute of Crop Science (NICS), RDA)
Jeong, Jae-Hyeok (National Institute of Crop Science (NICS), RDA)
Lee, Hyeon-Seok (National Institute of Crop Science (NICS), RDA)
Choi, In-Bae (National Institute of Crop Science (NICS), RDA)
Ahn, Seung-Hyeon (National Institute of Crop Science (NICS), RDA)
Jeong, Han-Young (National Institute of Crop Science (NICS), RDA)
Yoon, Jong-Tak (National Institute of Crop Science (NICS), RDA)
Choi, Kyung-Jin (National Institute of Crop Science (NICS), RDA)

Publication Information

KOREAN JOURNAL OF CROP SCIENCE / v.63, no.2, 2018 , pp. 112-119 More about this Journal

Abstract

Heat stress during the ripening stage reduces the yield and quality of rice. Considering the adverse effects of global warming, it is necessary to breed heat stress tolerant rice cultivars and analyze their stress tolerance characteristics. We investigated the ripening characteristics and antioxidant enzyme activity of Ilmi under heat stress condition during the ripening stage. Ripening rate, 1000 brown grain weight, and rice quality of Ilmi were not significantly changed by heat stress during the ripening stage. Leaf chlorophyll, chlorophyll a/b ratio, and malondialdehyde (MDA) contents of Ilmi leaves were also less changed than those of Ilpum. These results strongly suggested that Ilmi has heat tolerance characteristics during the ripening stage. Analysis of antioxidant enzyme activity of Ilmi revealed that peroxidase (POX) activity was significantly higher than that of Ilpum, and showed a significant correlation with the change in chlorophyll a/b ratio and hydrogen peroxide content of flag leaves of Ilmi. These data suggest that the high POX enzyme activity of Ilmi could be considered one of its major heat tolerance characteristics.

Keywords

antioxidant; heat stress; Ilmi; reactive oxygen species; tolerance;

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Times Cited By KSCI : 2 (Citation Analysis)

Reference
Cited By KSCI

1	Almeselmani, M., P. S. Deshmukh, R. K. Sairam, S. R. Kushwaha, and T. P. Singh. 2006. Protective role of antioxidant enzyme under high temperature stress. Plant Science 171 : 382-388. DOI
2	Asada, K. and M. Takahashi. 1987. Photoinhibition. In:Kyle D.J., Osmond C.B., Arntzen C.J (eds.). Production and Scavenging of active Oxygen in Photosynthesis. Amsterdam: Elsevier P. 227-287.
3	Asatsuma, S., C. Sawada, A. Kitajim, T. Asakura, and T. Mitsui. 2006. a-amylase affects starch accumulation in rice grains. Journal of Applied Glycoscience 53 : 187-192. DOI
4	Bhattacharjee, S. 2005. Reactive oxygen species and oxidative burst: Roles in stress, senescence and signal transduction in plant. Current Science 89(7) : 1113-1121.
5	Chen, G., Z. Q. Q. Wang, Liu, F. Xiong, Y. J. Gu, and G. J. Gu. 2006. Development and substance accumulation of caryopsis in transgenic rice with antisense Wx gene. Rice Science 13 : 106-12.
6	Cheng, F., L. Zhong, N. Zhao, Y. Liu, and G. Zhang. 2005. Temperature induced changes in the starch components and biosynthetic enzymes of two rice varieties. Plant Growth Regul. 46 : 87-95. DOI
7	Dat J. F., H. Lopez-Delgado, C. H. Foyer, and M. I. Scott. 1998. Parallel changes in $H_2O_2$ and catalase during thermostolerance induced by salicylic acid or heat acclimation in mustard seedling. Plant Physiology 110: 1351-1357.
8	Dat, J. F., S. Vandenabeele, E. Vranova, M. Van Montagu, D. Inze, and V. Bresusegem. 2000. Dual action of the active oxygen species during plant stress responses. Cell Mol. Life Sci. 57 : 779-795. DOI
9	Dolferus, R., X. M. Ji, and R. A. Richards. 2011. Abiotic stress and control of grain number in cereals. e Plant Science 181 : 331-41. DOI
10	IPCC. 2013. Fifth Assessment Report (AR5). WMO/UNEP.
11	Lloret, F., A. Escudero, J. M. Iriondo, J. Martínez-Vilalta, and F. Valladares. 2012. Extreme climatic events and vegetation: the role of stabilizing processes. Global Change Biol 18(3), 797-805. DOI
12	Jeong, J. U., Y. S. Shin, I. S. Choi, J. K. Chang, M. K. Kim, J. H. Lee, H. M. Park, C. I. Yang, Y. H. Jeon, J. P. Suh, I. B. Choi, J. M. Jeong, N. S. Sung, J. H. Lee, M. R. Yoon, and C. K. Kim. 2016. Blast resistant early maturing rice 'Jungmo 1024' with high temperature tolerance during grain filling stage. Korean J. Breed. Sci. 48(1) : 72-84. DOI
13	Kaneko, K., M. Sasaki, N. Kuribayashi, H. Suzuki, Y. Sasuga, T. Shiraya, T. Inomata, K. Itoh, M. Baslam, and T. Mitsui. 2016. Proteomic and glycomic characterization of rice chalky grains produced under moderate and high temperature conditions in field system. Rice 9:26. DOI
14	Kim, J., J. Shon, C. Lee, Y. Yong, W. Yang, Y. Kim, and B. Lee. 2011. Relationship between grain filling duration and leaf senescence of temperate rice under high temperature. Field Crops Research 122 : 207-213. DOI
15	Kramer, P. J. and T. Kozlowski. 1979. Physiology of wood plants. Academic Press, New York, pp. 811.
16	Kura-Hotta, M., K. Satho, and S. Kathh. 1987. Relationship between photosynthesis and chlorophyll content during leaf senescence of rice seeding. Plant cell physiology 28(7), 1321-1329.
17	Majid, K., G. Roza, J.S. Shahzad, and Z. M. Roghayyeh. 2011. The leaf chlorophyll content and stress resistance relationship considering in Corn cultivars (Zea. Mays). Advances in Environmental Biology 5(1), 118-122, 2011.
18	Morita, S. 2011. High temperature damage in rice and its measures. Tokyo : Nosan Gyoson Bunka Kyokai.
19	Morita, S., J. Yonemaru, and J. Takanashi. 2005. Grain growth and endosperm cell size under high night temperatures in rice (Oryza sativa L.). Annals of Botany 95 : 695-701. DOI
20	Nakagawa, H., H. Tanaka, N. Tano, and H. Nagahata. 2006. Effects of leaf and panicle clipping on the occurrence of various types of chalky kernels in rice. Hokuriku Crop Science 41 : 32-44.
21	Sairam, R. K. G. C. Srivastava. and D. C. Saxena. 2000. Increased antioxidant activity under elevated temperature: a mechanism of heat stress tolerance in wheat genotype. BIOLOGIA PLANTARUM 43(2) : 245-251. DOI
22	Pearcy, R. W. and D. A. Sims. 1994. Photosynthetic acclimation to changing light environments: scaling from the leaf to the whole plant. In Ecophysiological Processes Above and Below Ground. Eds. M.M. Caldwell and R.W. Pearcy. Academic Press, New York, pp. 145-174.
23	Peng, S., J. Huang, J. E. Sheehy, R. C. Laza, R. M. Visperas, X. Zhong, G. S. Centeni, G. S. Khush, and K. G. Cassman. 2004. Rice yields decline with higher night temperature from global warming. Proceedings of the National Academy of Sciences USA, 101 : 9971-9975. DOI
24	Porter, J. R. and M. Gawith. 1999. Temperatures and the growth and development of wheat. European Journal of Agronomy. 10: 23-36. DOI
25	Savicka, M. and N. Skute. 2010. Effects of high temperature on malondialdehyde content superoxide production and growth changes in wheat seedlings (Triticum aestivum L.). Ekologija 56(1) : 26-33. DOI
26	Shamsi, K. 2010. The effects of drought stress on yield, relative water content, proline, soluble carbohydrates and chlorophyll of bread wheat cultivars. Journal of Animal & Plant Sciences 8(3) : 1051-1060.
27	Shon, J. Y., J. H. Kim, C. K. Lee, and W. H. Yang. 2015. Effect of high temperature on leaf physiological changes as chlorophyll composition and photosynthesis rate of rice. Korean J. Crop Sci. 60(3) : 266-272. DOI
28	Terashima, K., Y. Saito, N. Sakai, T. Watanabe, T. Ogata, and S. Akita. 2001. Effects of high air temperature in summer of 1999 on ripening and grain quality of rice. Japanese Journal of crop science 70 : 449-458. DOI
29	Siebert, S., F. Ewert, E. E. Rezaei, H. Kage, and B. R. Gra. 2014. Impact of heat stress on crop yield-on the importance of considering canopy temperature. Environmental Research Letters 9 : 044012. DOI
30	Tashiro, T. and I. F. Wardlaw. 1991. The effect of high temperature on kernel dimensions and the type and occurrence of kernel damage in rice. Australian Journal of Agricultura Research 42 : 485-496. DOI
31	Ugarte, C., D. F. Calderini, and G. A. Slafer. 2007. Grain weight and grain number responsiveness to pre-anthesis temperature in wheat, barley and triticale. Field Crop Research 100 : 240-8. DOI
32	Yang, W. 2006. Physiological characterization of high yielding genotypes of rice (Oriza sativa L.) in the tropical irrigated system. University of Philippines at Los Banos. Ph. D. Thesis. pp. 51-52.
33	Yugandhar, P., K. B. Ramana, P. Madhusmita, P. V. Vishnu, R. D. Nageswara, R. V. Sitapathi, D. Subrahmanyam, and N. Sarla. 2013. Characterization of a Nagina22 rice mutant for heat tolerance and mapping of yield traits. Rice 6 : 36. DOI
34	Zhang, H., L. Duan, J. S. Dai, C. Q. Zhang, J. Li, M. H. Gu, Q. Q. Liu., Y. Zhu. 2014. Major QTLs reduce the deleterious effects of high temperature on rice amylose content by increasing slicing efficiency of Wx pre-mRNA. Theoretical and Applied Genetics 127(2) : 273-282. DOI