Scientia Agricultura Sinica ›› 2015, Vol. 48 ›› Issue (1): 23-32.doi: 10.3864/j.issn.0578-1752.2015.01.03

• CROP GENETICS & BREEDING·GERMPLASM RESOURCES·MOLECULAR GENETICS • Previous Articles     Next Articles

Differentially Proteomics Analysis of Pre-Harvest Seed Deterioration and Deterioration Resistance in Spring Soybean

Li-ru1, WANG Shuang1, NIU Juan1, MA Hong-yu1, SHU Ying-jie1, YANG Yan1, GU Wei-hong2, MA Hao1   

  1. 1State Key Laboratory of Crop Genetics & Germplasm Enhancement, College of Agriculture, Nanjing Agricultural University, Nanjing 210095
    2Horticultural Research Institute, Shanghai Academy of Agricultural Sciences, Shanghai 201106
  • Received:2014-06-11 Online:2015-01-01 Published:2015-01-01

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Abstract: 【Objective】 Soybean seed is susceptible to high temperature and humidity (HTH) stress resulting in pre-harvest deterioration during its development and maturation (R6 or R7), which limits the production and utilization of soybean in south China. The aim of the present study is to reveal the pre-harvest seed deterioration and deterioration resistance mechanism of spring soybean under HTH stress at proteomic level, thus laying a foundation for breeding new cultivars.【Method】When the deterioration-sensitive cultivar Ningzhen No.1 and deterioration-tolerant cultivar Xiangdou No.3 developed to physiological period (R7), their plants were treated under HTH stress and control for 1, 5, 10, 16 and 24 h, respectively. The extracted proteins from the developing seed of treatment and control were analyzed by two-dimensional electrophoresis (2-DE), and the differentially expressed proteins were identified by MALDI-TOF/TOF. 【Result】Approximately 700 protein spots were detected on each 2-DE gel. Of them, 50 were found to be significantly changed in abundance, with 33 being successfully identified by MALDI-TOF/TOF. The identified differentially expressed proteins were involved in cell rescue and defense (9%), redox homeostasis (12%), protein synthesis (3%), energy metabolism (15%), transport pathway (15%), protein destination and storage (31%). Moreover, the function of 5 identified proteins is unknown. 【Conclusion】Pre-harvest deterioration-resistant cultivar Xiangdou No.3 possessed the greater ability of ROS scavenging and cell rescue and defense than deterioration-sensitive cultivar Ningzhen No.1 under HTH tress, which may be the major reasons why it is more deterioration-resistant than the latter.

Key words: spring soybean seed, pre-harvest seed deterioration, deterioration resistance, high temperature and humidity, proteomics

[1]    韩天富, 盖钧镒. 世界菜用大豆生产、贸易和研究的进展. 大豆科学, 2002, 21(4): 278-284.
Han T F, Gai J Y. Advance in production, trade and research of vegetable soybean in the world. Soyben Scinece, 2002, 21(4): 278-284. (in Chinese)
[2]    Gibson L R, Mullen R E.Soybean seed quality reductions by high day and night temperature. Crop Science, 1996, 36: 1615-1619.
[3]    乔燕祥, 周建萍, 田齐建, 穆志新. 大豆种子老化过程中生理特性变化的研究. 植物遗传资源学报, 2010, 11(5) : 616-620.
Qiao Y X, Zhou J P, Tian Q J, Mu Z X. Changing of physiological characteristics of soybean seeds in aging course. Journal of Plant Genetic Resources, 2010, 11(5): 616-620. (in Chinese)
[4]    王芳, 王丽群, 田鑫, 顾卫红, 麻浩. 中国南方春大豆收获前后种子劣变的抗性研究.中国农业科学, 2007, 40(11): 2637-2647.
Wang F, Wang L Q, Tian X, Gu W H, Ma H. Pre-harvest and post-harvest seed deterioration resistance of spring soybean germplasm in South China. Scientia Agricultura Sinica, 2007, 40(11): 2637-2647. (in Chinese)
[5]    Saha R R, Sultana W. Influence of seed ageing on growth and yield of soybean. Bangladesh Journal of Botany, 2008, 37: 21-26.
[6]    Ren C, Bilyeu K D, Beuselinck P R. Composition, vigor, and proteome of mature soybean seeds developed under high temperature. Crop Science, 2009, 49: 1010-1022.
[7]    唐桂香, 汪自强, 董明远. 春播和秋播对南方春大豆种子活力的影响. 作物学报, 1998, 21(2):243-247.
Tang G X, Wang Z Q, Dong M Y. Effects of plantings in spring and fall on the vigor of spring soybean seed in southern region. Acta Agronomica Sinica, 1998, 21(2): 243-247. (in Chinese)
[8]    McDonald M B. Seed deterioration: Physiology, repair and assessment. Seed Science and Technology, 1999, 27: 177-237.
[9]    Egli D B, TeKrony D M, Heitholt J J. Air temperature during seed filling and soybean seed germination and vigor. Crop Science, 2005, 45: 1329-1335.
[10]   唐善德, 黄敏珍, 成金莲. 春大豆种子劣变的研究. 大豆科学, 1994, 13(3): 230-236.
Tang S D, Huang M Z, Cheng J L. A study on seed deterioration in spring soybeans. Soybean Science, 1994, 13(3): 230-236. (in Chinese)
[11]   Wien H, Kueneman E. Soybean seed deterioration in the tropics: II. Varietal differences and techniques for screening. Field Crops Research, 1981, 4: 123-132.
[12]   马国荣. 国际热带农业研究所(IITA)的大豆育种. 大豆科学, 1989, 8(2): 203-205.
Ma G R. Soybean breeding program in the International Institute of Tropical Agriculture (IITA). Soybean Science, 1989, 8(2): 203-205. (in Chinese)
[13]   孟祥栋. 菜用大豆种子劣变与生理生化变化的关系. 大豆科学, 1993, 12: 259-264.
Meng X D. Relationship between seed deterioration and physiological and biochemical changes of vegetable soybeans. Soybean Science, 1993, 12: 259-264. (in Chinese)
[14]   赵垦田, 李立华. 人工老化过程红松种胚细胞物质外渗和超微结构变化. 东北林业大学学报, 2000, 28(3): 5-7.
Zhao K T, Li L H. Cellular substance exudation and ultrastructural change of seed embryos of pinus koraiensis artificially accelerated aging. Journal of Northeast Forestry University, 2000, 28(3): 5-7. (in Chinese)
[15]   王慧超, 何士敏, 李昌满. PEG渗调处理对植物种子的影响. 安徽农业科学, 2008, 36(6) :2224-2226.
Wang H C, He S M, Li C M. Effect of PEG osmotic conditioning treatment on plant seed. Journal of Anhui Agriculture Science, 2008, 36(6): 2224-2226. (in Chinese)
[16]   Wang L Q, Ma H, Song L R, Shu Y J, Gu W H. Comparative proteomics analysis reveals the mechanism of pre-harvest seed deterioration of soybean under high temperature and humidity stress. Journal of Proteomics, 2012, 75(7): 2109-2127.
[17]   舒英杰, 周玉丽, 陶源, 王爽, 杨艳, 张国敏, 麻浩. 模拟田间劣变对生理成熟期春大豆植株生长及种子活力的影响. 大豆科学, 2013, 32(5): 635-639.
Shu Y J, Zhou Y L, Tao Y, Wang S, Yang Y, Zhang G M, Ma H. Effect of simulated pre-harvest deterioration stress on plant growth and seed vigor of spring soybean at physiological maturity stage. Soybean Science, 2013, 32(5): 635-639. (in Chinese)
[18]   Parrish D J, Leopold A C. On the mechanism of aging in soybean seeds. Plant Physiology, 1978, 61: 365-369.
[19]   Jain A, Shivanna K R. Loss of viability during storage is associated with changes in membrane phosphohpid. Physology Chemistry, 1989, 28 : 999-1002.
[20]   Clarke N A, James P E. The effects of priming and accelerated ageing upon the nucleic acid content of leek seeds and their embryos. Journal of Experimental Botany, 1991, 42: 261-268.
[21]   Krober V A, Collins F I. Effects of weather damage on the chemical composition of soybeans. Journal of American Oil Chemists Society, 1948, 25: 296-298.
[22]   Ching T M. Adenosine tnphosphate and seed vigor// Khan A A. ed. The Physiology and Biochemistry of Seed Development, Dormancy, and Germination. Elsevier New York, 1982: 487-505.
[23]   Duke S H, Kakefuda G, Henson C A, Loeffler N L. Role of the testa epidermis in the leakage of intracellular substances from imbibing soybean seeds and its implications for seedling survival. Physiologia Plantarum, 1986, 68: 625-631.
[24]   Bradford M M. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Analytical Biochemistry, 1976, 72: 248-254.
[25]   Blum H, Beier H, Gross H J. Improved silver staining of plant proteins, RNA and DNA in polyacrylamide gels. Electrophoresis, 1987, 8: 93-99.
[26]   Yao Y, Yang Y W, Liu J Y. An efficient protein preparation for proteomic analysis of developing cotton fibers by two-dimensional gel electrophoresis. Electrophoresis, 2006, 27: 4559-4569.
[27]   Ma H Y, Song L R, Shu Y J, Wang S, Niu J, Wang Z K, Yu T, Gu W H, Ma H. Comparative proteomic analysis of seedling leaves of different salt tolerant soybean genotypes. Journal of Proteomics, 2012, 75(6): 1529-1546.
[28]   Zhang L, Yu Z F, Jiang L, Jiang J, Luo H B, Fu L R. Effect of post-harvest heat treatment on proteome change of peach fruit during ripening. Journal of Proteomics, 2011, 74: 1135-1149.
[29]   Huang H, Møller I M, Song S Q. Proteomics of desiccation tolerance during development and germination of maize embryos. Journal of Proteomics, 2012, 75: 1247-1262. 
[30]   Hashiguchi A, Sakata K, Komatsu S. Proteome analysis of early-stage soybean seedlings under flooding stress. Journal of Proteome Research, 2009, 8: 2058-2069.
[31]   Wan X Y, Liu J Y. Comparative proteomics analysis reveals an intimate protein network provoked by hydrogen peroxide stress in rice seedling leaves. Molecular and Cellular Proteomics, 2008, 10: 1469-1488.
[32]   Kim Y J, Lee S, Lee H M. Comparative proteomics analysis of seed coat from two black colored soybean cultivars during seed development. Plant Omics Journal, 2013, 6(6): 456-463. 
[33]   Major I T, Constabel C P. Functional analysis of the Kunitz trypsin inhibitor family in poplar reveals biochemical diversity and multiplicity in defense against herbivores. Plant Physiology, 2008, 146: 888-903.
[34]   Wang J Q, Suen P K, Xu Z F, Jiang L W. A 64 kDa sucrose binding protein is membrane-associated and tonoplast-localized in developing mung bean seeds. Journal of Experimental Botany, 2009, 60(2): 629-639.
[35]   Salekdeh G H, Siopongco J, Wade L J, Ghareyazie B, Bennett J. Proteomic analysis of rice leaves during drought stress and recovery. Proteomics, 2002, 2(9): 1131-1145.
[36]   Pacold I, Anderson L E. Chloroplast and cytoplasmic enzymes: VI. Pea leaf 3-phosphoglycerate kinases. Plant Physiology, 1975, 55: 168-171.
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