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Acta Agron Sin ›› 2017, Vol. 43 ›› Issue (05): 763-776.doi: 10.3724/SP.J.1006.2017.00763

• TILLAGE & CULTIVATION·PHYSIOLOGY & BIOCHEMISTRY • Previous Articles     Next Articles

Effects of Plant Growth Regulators on Fiber Growth and Development in Colored Cotton Ovule Culture in vitro

ZHANG Xiao-Meng**,LIU Song-Jiang**,GONG Wen-Fang,SUN Jun-Ling,PANG Bao-Yin,DU Xiong-Ming*   

  1. Institute of Cotton Research of Chinese Academy of Agricultural Sciences / State Key Laboratory of Cotton Biology, Anyang 455000, China
  • Received:2016-07-14 Revised:2017-01-21 Online:2017-05-12 Published:2017-02-17
  • Contact: Du Xiongming, E-mail: dxm630723@163.com E-mail:18738237057@163.com
  • Supported by:

    This study was supported by the National Natural Science Foundation of China (31601353).

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Abstract:

Naturally colored cotton is an ideal textile raw material for the environmental protection and human health. The ovule of cotton varieties Z1-61, Lyumian CC28 and RT-baixu (CK) was cultured in the media with different concentrations of plant growth regulators (MeJA, SHAM, BR, BRz, FLD, ETH, CoCl2, PAL inhibitor, 4CL inhibitor, Urea, and Chl). After 30 days, the fiber color, fiber length, ovule fresh weight, ovule dry weight and fiber dry weight were determined and analyzed with Duncan's new multiple range method. Under the treatments of salicylhydroxamic, phenylalanine ammonia solution enzyme inhibitor and 4CL inhibitor, the color of Z1-61 and Lyumian CC28 cotton fiber was light, and the higher the concentration of the Salicylhydroxamic acid, the lighter of the cotton fiber color. BRz (2.5 μmol L–1) was conducive to the pigment accumulation in brown cotton fiber, while did not have any significant effect on the pigment appearance of green cotton. Both FLD and CoCl2 made the color of brown cotton fiber lighter, while CoCl2 had little influence on the green color cotton fiber and inhibited the formation of callus. Moreover, salicylhydroxamic acid, BRz, FLD, CoCl2, phenylalanine ammonia solution enzyme inhibitor or 4CL inhibitor decreased the fiber length, ovule fresh weight, fiber dry weight and ovule dry weight. In addition, 5 g L-1 urea or 1 mg L-1 Chl were advantageous to the brown cotton fiber pigment synthesis. In conclusion, the growth regulators tested in this study revealed the correlations among pigments synthesis, hormone, flavonoid metabolism and protein metabolism, which would be useful for developing colored cotton cultivars.

Key words: Colored cotton, Fiber growth, Pigment synthesis, Plant growth regulators

[1]董合忠, 李维江, 唐薇, 张冬梅. 彩色棉纤维发育与色素形成. 中国棉花, 2004, 31(2): 2–4 Dong H Z, Li W J, Tang W, Zhang D M. Pigment synthesis and cotton fiber development of color cotton. China Cotton, 2004, 31(2): 2–4 (in Chinese) [2]詹少华, 林毅, 蔡永萍, 文汉. 天然棕色棉色素分布规律及色素合成与纤维发育的关系. 棉花学报, 2006, 18(3): 170–174 Zhan S H, Lin Y, Cai Y P, Wen H. The pigment distribution regulation of the natural brown cotton and relations between pigment synthesis and cotton fiber development. Cotton Sci, 2006, 18(3): 170–174 (in Chinese with English abstract) [3]詹少华, 林毅, 蔡永萍, 李正鹏. 天然棕色棉纤维色素光谱学特性及其化学结构初步推断. 植物学通报, 2007, 24: 99–104 Zhan S H, Lin Y, Cai Y P, Li Z P. Preliminary deductions of the chemical structure of the pigment brown in cotton fiber. Chin Bull Bot, 2007, 24: 99?104. (in Chinese with English abstract) [4]Ryser U, Meier H, Holloway P J. Identification and localization of suberin in the cell walls of green cotton fibres (Gossypium hirsutum L., var. green lint). Protoplasma, 1983, 117: 196–205 [5]胡超, 杨园园, 郭宁, 蔡永萍, 林毅, 高俊山, 姜家生. 棕色棉与白色棉缩合单宁单体儿茶素动态变化的比较. 植物生理学报, 2011, 47: 685–690 Hu C, Yang Y Y, Guo N, Cai Y P, Lin Y, Gao J S, Jiang J S. Comparison of dynamic changes in condensed tannin monomer catechins between brown cotton and white cotton. Plant Physiol J, 2011, 47: 685–690 (in Chinese with English abstract) [6]赵向前, 王学德. 天然彩色棉纤维色素成分的研究. 作物学报, 2005, 31: 456–462 Zhao X Q, Wang X D. Composition analysis of pigment in colored cotton fiber. Acta Agron Sin, 2005, 31: 456–462 (in Chinese with English abstract) [7]张美玲. 彩色棉纤维分化发育规律与色素成分研究. 山东农业大学博士学位论文, 山东泰安, 2013 Zhang M L. Exploration of Fiber Differentiation and Development and Pigment Component in Colored Cotton. PhD Dissertation of Shandong Agricultural University, Tai’an, China, 2013 (in Chinese with English abstract) [8]Schmutz A, Buchala A J, Ryser U. Changing the dimensions of suberin lamellae of green.fibers with a specific inhibitor of the endoplasmic reticulum-associated fatty acid elongases. Plant Physiol, 1996, 110: 403–411 [9]汪淼, 陈沙沙, 蔡永萍, 林毅, 孙旭, 郭宁, 高俊山, 姜家生. 光质对棕色棉纤维色素形成的影响. 棉花学报, 2013, 25: 329–333 Wang M, Chen S S, Cai Y P, Lin Y, Sun X, Guo N, Gao J S, Jiang J S. Effect of light quality on pigment formation in brown cotton fiber. Cotton Sci, 2013, 25: 329–333 (in Chinese with English abstract) [10]Gong W F, He S P, Tian J H, Sun J L, Pan Z E, Jia Y H, Sun G F, Du X M. Comparison of the transcriptome between two cotton lines of different fiber color and quality. PloS One, 2014, 9: e112966 [11]Waghmare V N, Koranne K D. The present situation, problems and future potential of the colored cotton cultivation. Breed Abroad, 2000, 19: 6 [12]王学德, 李悦有. 彩色棉纤维发育的特性研究. 浙江大学学报(农业与生命科学版), 2002, 28: 237–242 Wang X D, Li Y Y. Study on characteristics of colored cotton fiber development. J Zhejiang Univ (Agric Life Sci), 2002, 28: 237–242 (in Chinese with English abstract) [13]潘兆娥, 杜雄明, 孙君灵, 周忠丽, 庞保印. 遮光对彩色棉的色泽及纤维品质的影响. 棉花学报, 2006, 18: 264–268 Pan Z E, Du X M, Sun J L, Zhou Z L, Pang B Y. Influences of boll shading on fiber color and fiber quality of colored cotton. Cotton Sci, 2006, 18: 264–268 (in Chinese with English abstract) [14]袁淑娜. 彩色棉纤维发育特性以及基于细胞质雄性不育的彩色长绒棉育种研究. 浙江大学博士学位论文, 浙江杭州, 2009 Yuan S N. Studies on Characteristics of Colored Cotton Fiber Development and Breeding for Colored Cotton with Long Fiber Based on Cytoplasmic Male Sterility System. PhD Dissertation of Zhejiang University, Hangzhou, China, 2009 (in Chinese with English abstract) [15]Yuan S N, Malik W, Hua S J, Bibi N, Wang X D. in vitro inhibition of pigmentation and fiber development in colored cotton. J Zhejiang Univ (Science B), 2012, 13: 478–486 [16]Beasly C A, Ting I P. The effects of plant growth substances on in vitro fiber development from fertilized cotton ovules. Am J Bot, 1973, 60: 130–l39 [17]Shi Y H., Zhu SW, Mao X Z, Feng J X, Qin Y M, Zhang L, Cheng J, Wei L P, Wang Z Y, Zhu Y X. Transcriptome pro?ling molecular biological and physiological studies reveal a major role for ethylene in cotton ?ber cell elongation. Plant Cell, 2006, 18: 651–664 [18]Ling F, Lü M, Ni Z Y, Hu W R, Wang J. Digital image analysis of expansion growth of cultured cotton ovules with fibers and their responses to ABA in vitro Cell Dev Boil-Plant, 2011, 47: 369–374 [19]谭琨岭. 菜油凿醇和谷菌醇对棉花纤维发育的影响. 西南大学硕士学位论文, 重庆, 2009 Tan K L. The Function of Campesterol and Sitosterol for the Cotton Fiber Development. MS Thesis of Southwest University, Chongqing, China, 2009 (in Chinese with English abstract) [20]Pang Y, Wang H, Song W Q, Zhu Y X. The cotton ATP synthase δ1 subunit is required to maintain a higher ATP/ADP ratio that facilitates rapid fiber cell elongation. Plant Biol (Stuttg), 2010, 12: 903–909 [21]叶春燕, 欧婷, 陈进红, 何秋伶, 祝水金. 培养基、胚龄和激素配比对棉花胚珠离体培养纤维生长发育的影响. 棉花学报, 2013, 25: 17–23 Ye C Y, Ou T, Chen J H, He Q L, Zhu S J. Effect of medium, ovule age, and hormone combinations on the fiber growth and development of cotton ovule culture in vitro. Cotton Sci, 2013, 25: 17–23 (in Chinese with English abstract) [22]徐楚年, 董合忠. 棉纤维发育与棉胚珠培养纤维. 北京: 中国农业大学出版社, 2006 Xu C N, Dong H Z. Fiber Growth and Development of Cotton Ovule Culture in vitro. Beijing: China Agricultural University Press, 2006 (in Chinese) [23]Chen J Y, Wen P F, Kong W F. Effect of salicylic acid on phenylpropanoids and phenylalan in ammonialyase in harvested grapeberries. Postharvest Biol Technol, 2006, 40: 64–72 [24]Wolski E A, Henriouez M A, Adaml R. Induction of defense genes and secondary metabolites in saskatoons (Amelanchier alnifolia Nutt.) in response to Entomosporium mespili using jasmonic acid and Canada milkvetch extracts. Environm Exp Bot, 2010, 68: 273–282 [25]Vom Endt D, Soarese Silva M, Kijne J W, Pasquali G, Memelink J. Identification of a bipartite jasmonate-responsive promoter element in the Catharanthus roseus ORCA3 transcription factor gene that interacts specifically with AT-Hook DNA-binding proteins. Plant Physiol, 2007, 144, 1680 [26]马杰, 胡文忠, 毕阳, 姜爱丽, 萨仁高娃. 茉莉酸甲酯处理对鲜切莴苣和甘蓝苯丙烷代谢的影响. 食品工业科技, 2013, 34: 333–335 Ma J, Hu W Z, Bi Y, Jang A L, Sa R G W. Effect of MeJA treatments on benzene propane metabolism in tissues of fresh-cut lettuce and cabbage. Sci Technol Food Industry, 2013, 34: 333–335 (in Chinese with English abstract) [27]谷晓策. 基于改造茉莉酸甲酯生物合成途径的丹参次生代谢工程新策略. 第二军医大学硕士学位论文, 上海, 2011 Gu X C. Novel Stratage of Secondary Metabolic Engineering in Salvia Miltiorrhiza-Based on the Reform of MeJA Biosynthetic Pathway. MS Thesis of Second Military Medical University, Shanghai, China, 2011 (in Chinese with English abstract) [28]Elwanm W M, Elhamahmym A M. Improved productivity and quality associated with salicylic acid application in green house pepper. Sci Hort, 2009, 122: 521–526 [29]Vitseva O, Varghese S, Freedman J E. Grape seed and skin extracts inhibit platelet function and release of reactive oxygen intermediates. J Cardiovasc Pharmacol, 2005, 46: 445–451 [30]黄婕. 油菜素内酯(BR)和IAA、BAP互作影响滇紫草细胞次生代谢及其生化机制研究. 南京大学硕士学位论文, 江苏南京, 2001 Huang J. BR and IAA, BAP Interactions Influence the Secondary Metabolism of Onosma paniculatum Cell and Its Biochemical Mechanism Research. MS Thesis of Nanjing University, Nanjing, China, 2001 (in Chinese with English abstract) [31]淦庆雷. 油菜素内酯影响滇紫草培养细胞中天然产物合成的分子机制研究. 南京大学硕士学位论文, 江苏南京, 2004 Gan Q L. Molecular Mechanism for Biosynthesis of the Natural Products Affected by Brassinolide in Onosma paniculatum Cultured Cells. MS Thesis of Nanjing University, Nanjing, China, 2004 (in Chinese with English abstract) [32]刘松江, 龚文芳, 孙君灵, 庞保印, 杜雄明. 生长物质对彩色棉胚珠离体培养纤维发育的影响. 中国农业科学, 2015, 48: 2127–2142 Liu S J, Gong W F, Sun J L, Pang B Y, DU X M. Effects of growth substances on the fiber growth and development of color cotton ovule culture in vitro. Sci Agric Sin, 2015, 48: 2127–2142 (in Chinese with English abstract) [33]任杰, 冷平. ABA和乙烯与甜樱桃果实成熟的关系. 园艺学报, 2010, 37: 199–206 Ren J, Leng P. Role of Abscisic acid and ethylene in fruit maturation of sweet cherry. Acta Hort Sin, 2010, 37: 199–206 (in Chinese with English abstract) [34]方荣俊, 赵华, 廖永辉. 乙烯对植物次生代谢产物合成的双重调控效应. 植物学报, 2014, 49: 626–639 Fang R J, Zhao H, Liao Y H. The dual regulation effect of ethylene on plant secondary metabolites synthesis. Chin Bull Bot, 2014, 49: 626–639 (in Chinese with English abstract) [35]刘金, 魏景立, 刘美艳. 早熟苹果花青苷积累与其相关酶活性及乙烯生成之间的关系. 园艺学报, 2012, 39: 1235–1242 Liu J, Wei J L, Liu M Y. The relationships between the enzyme activity of anthocyanin biosynthesis, ethylene release and anthocyanin accumulation in fruits of precocious apple cultivars. Acta Hort Sin, 2012, 39: 1235–1242 (in Chinese with English abstract) [36]Srinivasan V, Ciddi V, Bringi V. Metabolic inhibitors, elicitors, and precursors as tools for probing yield limitation in taxane production by Taxus chinensis cell cultures. Biotechnol Prog, 1996, 12: 457–465 [37]李贺勤, 杨华, 张娟娟, 宛晓春, 方从兵. PAL和4CL酶专一性抑制剂处理对野葛异黄酮生物合成的影响. 热带作物学报, 2009: 47–52 Li H Q, Yang H, Zhang J J, Wan X C, Fang C B. The influence of PAL and 4CL enzyme specific inhibitor treatment on kudzu isoflavone biosynthesis. Chin J Trop Crops, 2009: 47–52(in Chinese with English abstract) [38]梁颖, 李加纳. 甘蓝型油菜种皮色泽形成与相关酶及蛋白质含量的影响. 中国农业科学, 2004, 37: 522–527 Liang Y, Li J N. Relationship of the color formation and related enzymes and protein content of the spermoderms in Brassica napus. Sci Agric Sin, 2004, 37: 522–527 (in Chinese with English abstract)
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