Effect of Seed Coating Agents on External Morphology and Ultrastructure of Cotton Radicles and Seedlings under Low Temperature Treatments

doi:10.3969/j.issn.1000-6362.2017.04.006

Abstract

Abstract: In this study, ‘Xinluzhong 54’ cotton seeds coated with three different homemade seed coating agents (Mian 1, Mian 2 and Mian 3) were sown in plastic nutrition boxes and cultured at 25℃. On the 4th and 7th days when cotton seed radicles had grown into cotton seedlings, the coated cotton seeds were exposed to four low-temperature treatments at 5℃, 10℃, 15℃ and 20℃. The uncoated cotton seeds exposed to the same low-temperature treatments served as the control group (CK). The external morphologies and ultrastructures of the cotton radicles and seedlings were observed at 24 hours after low-temperature exposure to explore the effects of seed coating agents on improving the cold resistance of cotton by simulating the late spring cold climate in Xinjiang Province. The results showed that there was no significant difference between the coated and uncoated treatments at 20℃. Cotton seeds germinated normally at the germination rate of 92.24%-95.51%. The radicle growth lengths of the three different seed coating agents were 3.66-3.81cm, and the cotton seedlings grew well with dark green leaves and erect stems. The mitochondrial structure of radicle cells was complete, and the structures of mitochondria and chloroplasts in mesophyll cells were normal. Compared with the control, the seed germination rate of the coated seeds increased by 4.45-6.98 percentage points at 15℃. The radicle growth speed declined, but the growth amount increased by 25.27%-36.05%. The cotton seedlings grew well with dark green leaves and erect stems. Mitochondria cristae in radicle cells were clear. In addition, the structures of chloroplasts and mitochondria in mesophyll cells were clear, which were significantly better than after CK treatment. Cotton seed germination was inhibited at 10℃, but the germination rate of the coated seeds increased by 0.73-4.25 percentage points compared with that of the uncoated seeds. Radicle growth was limited, and the leaves were dark green. Approximately 19.15%-42.55% of the seedling leaves drooped and wilted. There were more mitochondria and endoplasmic reticula in the radicle cells of seedlings compared with that in seedlings from uncoated seeds. The outline of the chloroplast in mesophyll cells was clear with few inclusions. The Main 1 treatment was better than the other treatments. The cotton germination rate after different treatments was lower than 50.00% at 5℃. The seedling leaves in the uncoated group lost color and wilted with a wilting rate of 74.47%, whereas that of the coated treatment group was 60.42%-67.45%. The mitochondrial structure in the radicle cells was clear, and the mitochondrial structure in mesophyll cells was normal, while chloroplasts expanded into a spherical shape. The grana lamellar structure disintegrated, inclusions were turbid, and no significant difference was observed between coated and uncoated treatment groups. Our results show that seed coating agents can stimulate cotton seed germination, increase the seed germination rate and radicle growth speed under low-temperature treatments, protect the external morphology and cell ultrastructure stability of cotton radicles and seedlings, maintain normal growth, and enhance the ability of seedlings to resist damage from the low-temperature climate.

Key words: Seed coating agents, Cotton, Low temperature stress, External morphology, Ultrastructure

LEI Bin, LI Jin, DUAN Liu-sheng, ZHANG Peng-zhong, LI Jie, TAN Wei-ming. Effect of Seed Coating Agents on External Morphology and Ultrastructure of Cotton Radicles and Seedlings under Low Temperature Treatments[J]. Chinese Journal of Agrometeorology, 2017, 38(04): 248-256.

References

[1]新疆维吾尔自治区统计局.新疆统计年鉴[M].中国统计出版社,2015:363-369. Statistic Burean of Xinjiang Uygur Autonomous Region.Xinjiang statistical yearbook[M].China Statistics Press, 2015:363-369.(in Chinese) [2]严志丹.2012年阿拉尔市棉花生育期气象条件分析[J].新疆农垦科技,2014,(8):51-52. Yan Z D.Analysis of cotton meteorological conditions in Alar in 2012[J].Xinjiang Farmland Reclamation Science and Technology,2014,(8):51-52.(in Chinese) [3]刘玉涛,王瑾.低温天气对棉花播种出苗的影响及对策[J].中国种业,2011,(2):48. Liu Y T,Wang J.Effects of low temperature weather on the seed emergence of cotton and measures[J].China Seed Industry,2011, (2):48.(in Chinese) [4]Ruelland E,Vaultier M N,Zachowski A.Cold signalling and cold acclimation in plants[J].Advances in Botanical Research,2009, 49:35-150. [5]王钰静,谢磊,李志博,等.低温胁迫对北疆棉花种子萌发的影响及其耐冷性差异评价[J].种子,2014,33(5):74-77. Wang Y J,Xie L,Li Z B,et al.Effects of low temperature stress to germination of cotton seeds and evaluation of their cold resistance in northern Xinjiang[J].Seed,2014,33(5):74-77.(in Chinese) [6]Zeinolabedin J,Rohola H,Saeed S.Chilling stress in plants[J]. International Journal of Agriculture and Crop Sciences,2013, 24(5):2961-2968. [7]吴学宏,刘西莉,王红梅,等.我国种衣剂的研究进展[J].农药,2003,42(5):1-5. Wu X H,Liu X L,Wang H M,et al.Progressing on the study of seed coating formulations in China[J].Pesticides,2003,42(5): 1-5.(in Chinese) [8]李进,段俊杰,努尔买买提·努尔合加,等.种衣剂对棉花幼苗生长及抗寒能力的影响[J].新疆农业科学,2015,52(11):1997- 2003. Li J,Duan J J,Nu E M M T,et al.Effect of seed coating agents on seedling growth and cold resistance of cotton[J].Xinjiang Agricultural Sciences,2015,52(11):1997-2003.(in Chinese) [9]武辉,张巨松,石俊毅,等.棉花幼苗对不同程度低温逆境的生理响应[J].西北植物学报,2013,33(1):74-82. Wu H,Zhang J S,Shi J Y,et al.Physiological response of cotton seedlings under low temperature stress[J].Acta Bot. Boreal.- Occident.Sin,2013,33(1):74-82.(in Chinese) [10]杨云珠,陈文涛,郭金铨.PVA和PEG预处理对大豆种子在低温吸胀过程中胚根线粒体发育和超微结构的影响[J].植物学报,1992,31(6):432-436. Yang Y Z,Chen W T,Guo J Q.Effects of PVA and PEG pretreatment on development and ultrastructure of plumular root mitochondria in soybean seed during low temperature imbibition process[J].Acta Botanica Sinica,1992,31(6): 432-436.(in Chinese) [11]Ma S F,Lin C Y,Chen Y M.Comparative studies of chilling stress on alterations of chloroplast ultrastructure and protein synthesis in the leaves of chilling-sensitive(mungbean) and -insensitive(pea) seedlings[J].Bot.Bull.Academia Sinica,1990, 31:263-272. [12]杨凤仙,董俊梅,杨晓霞.低温胁迫下棉叶叶绿体、液泡超微结构的变化[J].山西农业大学学报,2001,(2):116-117. Yang F X,Dong J M,Yang X X.Varitions of the ultrastructure of the leaf cell of cotton under low temperature[J].Journal of Shanxi Agriculture University,2001,(2):116-117.(in Chinese) [13]Robert R W,Mcwilliam J R,Naylor A W.A comparative study of low temperature-induced ultrastructural alterations of three species with differing chilling sensitivities[J].Plant,Cell and Environment,1983,6(7):525-535. [14]彭倩,周青,叶亚新.La与UV-B辐射胁迫对大豆叶片细胞叶绿体超微结构的影响[J].中国农业气象,2008,29(1):33-36. Peng Q,Zhou Q,Ye Y X.Influence of La and Ultraviolet-B stress on chloroplast ultrastructure of soybean leaves [J].Chinese Journal of Agrometeorology,2008,29(1):33-36.(in Chinese) [15]付连双,王晓楠,王学东,等.低温驯化及封冻后不同抗寒性小麦品种细胞超微结构的比较[J].麦类作物学报, 2010,30(1):66-72. Fu L S,Wang X N,Wang X D,et al.Comparison of cell ultrastructure between winter wheat cultivars during cold acclimation and freezing period[J].Journal of Triticeae Crops,2010,30(1):66-72.(in Chinese) [16]吴凯,周晓阳.环境胁迫对植物超微结构的影响[J].山东林业科技,2007,(3):80-83. Wu K,Zhou X Y.Effects of Environmental stresses on plant ultrastructure[J].Shandong Forestry Science and Technology, 2007,(3):80-83.(in Chinese)