籽粒建成期高温胁迫持续时间对糯玉米籽粒产量和淀粉品质的影响

doi:10.3864/j.issn.0578-1752.2017.11.013

Abstract

Abstract: 【Objective】Clarifying the influence of heat stress durations at grain formation stage on grain yield and starch quality of waxy maize, which could afford a theoretical basis for waxy maize starch quality improvement.【Method】The pot trials were conducted at Yangzhou University in 2014 and 2015. After artificial pollination, heat stress treatments (35℃) were introduced by intelligent greenhouse and the heat stress durations were 1-5 d, 1-10 d, and 1-15 d after pollinations (DAP), respectively. The grain yield, grain protein and starch content, starch physicochemical parameters (starch granule size and distribution, chain-length distribution, crystallinity, pasting and thermal properties) were analyzed using Suyunuo 5 and Yunuo 7 as materials.【Result】Heat stress at grain formation stage reduced grain number and weight, which induced yield loss and the loss at 1-5, 1-10 and 1-15 DAP was 39.3%, 47.4%, 50.9%, respectively. Heat stress increased protein content and decreased starch content in grains, respectively. High temperature increased the starch average granule size and the granule size gradually decreased with the prolongation of heat stress durations. The starch maximum absorption wavelength, crystalline structure and setback viscosity present typical waxy character. Heat stress at grain formation stage increased the proportion of long-chains in amylopectin, and the values were the highest and the lowest at 1-10 DAP heat stress conditions for Suyunuo 5 and Yunuo 7, respectively, among different treatments. Relative crystallinity in response to heat stress durations was different between two varieties and two planting years. Generally, 10 d heat stress did not affect the pasting characteristics, while the peak, trough, breakdown, and final viscosities and pasting temperature were increased by 1-5 and 1-15 DAP heat stress and the increase of peak, trough and breakdown viscosities were the highest in 1-15 DAP heat stress. Compared with control, heat stress decreased gelatinization enthalpy and increased the other thermal characteristics. The gelatinization enthalpy was the lowest in 1-15 DAP heat stress, gelatinization temperatures were the highest in 1-5 DAP heat stress, and retrogradation percentage were similar among different heat stress durations.【Conclusion】Heat stress at grain formation reduced the grain yield and the reduction was gradually severe with the prolongation of heat stress durations. High temperature suppressed grain starch accumulation and increased the protein content. Starch pasting and thermal properties were changed as the starch granule size enlarged and proportion of long-chains in amylopectin increased. Among different heat stress durations, the peak and breakdown viscosities were the highest and setback viscosity was the lowest when high temperature was introduced at 1-15 DAP. The gelatinization temperatures were the highest under 1-5 DAP heat stress conditions and no difference was observed for retrogradation percentage among three heat stress treatments.

Key words: grain formation stage, waxy maize, heat stress, grain yield, starch quality

YANG Huan, SHEN Xin, LU DaLei, LU WeiPing. Effects of Heat Stress Durations at Grain Formation Stage on Grain Yield and Starch Quality of Waxy Maize[J].Scientia Agricultura Sinica, 2017, 50(11): 2071-2082.

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References

[1] IPCC. Working Group I Contribution to the IPCC Fifth Assessment Report Climate Change 2013: The Physical Science Basis, Summary for Policymakers. [2016-07-25]http://www.climatechange2013.org/ images/report/ WG1AR5_ALL_FINAL.pdf.

[2] Battisti D S,Naylor R L.Historical warnings of future food insecurity with unprecedented seasonal heat. Science,2009,323(5911):240-244.

[3] Jha Y C, Bohra A, Sinfh N P.Heat stress in crop plants: Its nature, impacts and integrated breeding strategies to improve heat tolerance. Plant Breeding, 2014, 133(6): 679-701.

[4] Kadam N N, Xiao G, Melgar R J, Bahuguna R N, Quinones C, Tamilselvan A, Prasad P V V, Jagadish K S V. Agronomic and physiological responses to high temperature, drought, and elevated CO₂ interactions in cereals. Advances in Agronomy, 2014, 127: 111-156.

[5] Cao Z Z, Pan G, Wang F B, Wei K S, Li Z W, Shi C H, Geng W, Cheng F M. Effect of high temperature on the expressions of genes encoding starch synthesis enzymes in developing rice endosperms. Journal of Integrative Agriculture, 2015, 14(4): 642-659.

[6] Aboubacar A, Moldenhauer K A K, McClung A M, Beighley D H, Hamaker B R. Effect of growth location in the United States on amylose content, amylopectin fine structure, and thermal properties of starches of long grain rice cultivars. Cereal Chemistry, 2006, 83(1): 93-98.

[7] Jiang H W, Dian W M, Wu P. Effect of high temperature on fine structure of amylopectin in rice endosperm by reducing the activity of the starch branching enzyme. Phytochemistry, 2003, 63(1): 53-59.

[8] Suzuki Y, Sano Y, Ishikawa T, Sasaki T, Matsukura U, Hirano H Y. Differences in starch characteristics of rice strains having different sensitivities to maturation temperatures. Journal of Agronomy and Crop Science, 2004, 190(3): 218-221.

[9] Yamakawa H, Hirose T, Kuroda M, Yamaguchi T. Comprehensive expression profiling of rice grain filling-related genes under high temperature using DNA microarray. Plant Physiology, 2007, 144(1): 258-277.

[10] Lu T J, Jane J L, Keeling P L, Singletary G W. Maize starch fine structures affected by ear developmental temperature. Carbohydrate Research, 1996, 282(1): 157-170.

[11] Lu D, Shen X, Cai X, Yan F, Lu W, Shi Y C. Effects of heat stress during grain filling on the structure and thermal properties of waxy maize starch. Food Chemistry, 2014, 143(1): 313-318.

[12] Lu D, Sun X, Yan F, Wang X, Xu R, Lu W. Effects of high temperature during grain filling under control conditions on the physicochemical properties of waxy maize flour. Carbohydrate Polymers, 2013, 98(1): 302-310.

[13] Lisle A J, Martin M, Fitzgerald M A. Chalky and translucent rice grains differ in starch composition and structure and cooking properties. Cereal Chemistry, 2000, 77(5): 627-632.

[14] Shi Y C, Seib P A, Bernardin J E. Effects of temperature during grain-filling on starches from 6 wheat cultivars. Cereal Chemistry, 1994, 71: 369-383.

[15] Matsuki J, Yasui T, Kohyama K, Sasaki T. Effects of environmental temperature on structure and gelatinization properties of wheat starch. Cereal Chemistry, 2003, 80(4): 476-480.

[16] Liu P, Guo W, Jiang Z, Pu H, Feng C, Zhu X, Peng Y, Kuang A, Little C R. Effects of high temperature after anthesis on starch granules in grains of wheat (Triticum aestivum L.). Journal of Agriculture Science, 2011, 149(2): 159-169.

[17] Thitisaksakul M, Jimenez R C, Abias M C, Beckles D M. Effects of environmental factors on cereal starch biosynthesis and composition. Journal of Cereal Science, 2012, 56(1): 67-80.

[18] Beckles D M, Thitisaksakul M. How environmental stress affects starch composition and functionality in cereal endosperm. Starch/Stärke, 2014, 66: 58-71.

[19] Li E P, Hasjim J, Singh V, Tizzotti M, Godwin I D, Gilbert R G. Insights into sorghum starch biosynthesis from structure changes induced by different growth temperatures. Cereal Chemistry, 2013, 90(3): 223-230.

[20] Mitsui T, Shiraya T, Kaneko K, Wada A K. Proteomics of rice grain under high temperature stress. Frontiers in Plant Science, 2013, 4: 36.

[21] 王珏, 封超年, 郭文善, 朱新开, 李春燕, 彭永欣. 花后高温胁迫对小麦籽粒淀粉积累及晶体特性的影响. 麦类作物学报, 2008, 28(2): 260-265.

Wang J, Feng C N, Guo W S, Zhu X K, Li C Y, Peng Y X. Effects of high temperature after anthesis on starch traits of grain in wheat. Journal of Triticeae Crops, 2008, 28(2): 260-265. (in Chinese)

[22] Zhong L J, Cheng F M, Wen X, Sun Z X, Zhang G P. The deterioration of eating and cooking quality caused by high temperature during grain filling in early-season indica rice cultivars. Journal of Agronomy and Crop Science, 2005, 191(3): 218-225.

[23] Lu D, Yang H, Shen X, Lu W. Effects of high temperature during grain filling on physicochemical properties of waxy maize starch. Journal of Integrative Agriculture, 2016, 15(2): 309-316.

[24] Yang H, Lu D, Shen X, Cai X, Lu W. Heat stress at different grain filling stages affects fresh waxy maize grain yield and quality. Cereal Chemistry, 2015, 92(3): 258-264.

[25] Lu D, Sun X, Yan F, Wang X, Xu R, Lu W. Effects of heat stress at different grain filling phases on the grain yield and quality of waxy maize. Cereal Chemistry, 2014, 91(2): 189-194.

[26] Cheikh N, Jones R J. Disruption of maize kernel growth and development by heat stress: Role of cytokinin/abscisic acid balance. Plant Physiology, 1994, 106(1): 45-51.

[27] Lu D, Lu W. Effects of protein removal on the physicochemical properties of waxy maize flours. Starch/Stärke, 2012, 64(11): 874-881.

[28] Fiedorowicz M, Rebilas K. Physicochemical properties of waxy corn starch and corn amylopectin illuminated with linearly polarized visible light. Carbohydrate Polymers, 2002, 50(3): 315-319.

[29] Chang Y, Lin J, Chang S. Physicochemical properties of waxy and normal corn starches treated in different anhydrous alcohols with hydrochloric acid. Food Hydrocolloids, 2006, 20(2/3): 332-339.

[30] Barnabás B, Jager K, Fehér A. The effect of drought and heat stress on reproductive processes in cereals. Plant, Cell & Environment, 2008, 31(1): 11-38.

[31] Powell N, Ji X, Ravash R, Edlington J, Dolferus R. Yield stability for cereals in a changing climate. Functional Plant Biology, 2012, 39(7): 539-552.

[32] Lindeboom N, Chang P R, Tyler R T. Analytical, biochemical and physicochemical aspects of starch granule size, with emphasis on small granule starches: A review. Starch/Stärke, 2004, 56(3/4): 89-99.

[33] Li L, Blanco M, Jane J. Physicochemical properties of endosperm and pericarp starches during maize development. Carbohydrate Polymers, 2007, 67(4): 630-639.

[34] 谭彩霞, 封超年, 郭文善, 朱新开, 李春燕, 彭永欣. 花后不同时期高温处理下小麦籽粒的淀粉合成及相关酶基因表达. 核农学报, 2012, 26(9): 1311-1316.

Tan C X, Feng C N, Guo W S, Zhu X K, Li C Y, Peng Y X. Effect of high temperature during different growth stage after anthesis on starch synthesis and related enzyme gene expression in wheat grains. Journal of Nuclear Agricultural Sciences, 2012, 26(9): 1311-1316. (in Chinese)

[35] 陆大雷, 郭换粉, 董策, 陆卫平. 生长季节对糯玉米淀粉粒分布和热力学特性的影响. 作物学报, 2010, 36(11): 1998-2003.

Lu D L, Guo H F, Dong C, Lu W P. Starch granule size distribution and thermal properties of waxy maize cultivars in growing seasons. Acta Agronomica Sinica, 2010, 36(11): 1998-2003. (in Chinese)

[36] 陆大雷, 王德成, 赵久然, 陆卫平. 生长季节对糯玉米淀粉晶体结构和糊化特性的影响. 作物学报, 2009, 35(3): 499-505.

Lu D L, Wang D C, Zhao J R, Lu W P. Crystalline structure and pasting properties of starch in eight cultivars of spring- and autumn-sown waxy corn. Acta Agronomica Sinica, 2009, 35(3): 499-505. (in Chinese)

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Effects of Heat Stress Durations at Grain Formation Stage on Grain Yield and Starch Quality of Waxy Maize

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