橘红肉甘薯块根类胡萝卜素的变化规律及其与主要经济性状的相关性

doi:10.3864/j.issn.0578-1752.2013.19.004

摘要/Abstract

摘要： 【目的】研究橘红肉甘薯块根鲜薯类胡萝卜素含量在生育过程中和品种间的变化规律及其与主要经济性状的相关性。【方法】试验于栽插后50、64、78、92、106、120和134 d调查15个橘红肉甘薯品种的最长蔓长，分枝数，结薯数，茎、叶、柄、块根干率，茎、叶、柄、块根鲜重，测定鲜薯类胡萝卜素含量，薯干淀粉、可溶性糖和粗蛋白含量，分析茎、叶、柄、块根干重，整株鲜重、干重，茎、叶、柄、块根干重占整株干重的百分比等数值，以及类胡萝卜素积累量与其余产量性状的变化和品质性状积累量日增长量的相关性。【结果】橘红肉甘薯块根类胡萝卜素含量在生长发育过程中出现总体平稳型、一直增加型和曲折上升型3种变化类型，对最长蔓长、块根鲜重、块根干重、光合产物的分配等经济性状的发育有不同的生物学响应。大多数橘红肉甘薯，尤其是一直增加型品种，其类胡萝卜素含量与最长蔓长、块根鲜重和干重、光合产物在块根的分配比例显著正相关，与光合产物在叶、柄的分配比例显著负相关，而与其它性状的相关性不高。类胡萝卜素日积累量增长量与块根鲜重、块根干重、淀粉、可溶性糖和粗蛋白积累量等日增长量呈正相关性，类胡萝卜素积累与块根膨大、干物质及营养物质积累存在协同关系。【结论】由于类胡萝卜素积累与干物质积累存在的协同关系在不同品种中的反应机制不同，类胡萝卜素含量在橘红肉品种间产生差异和分化，存在3种不同变化类型。

关键词: 橘红肉甘薯 , 类胡萝卜素 , 变化类型 , 经济性状 , 相关性

Abstract: 【Objective】Accumulation laws of carotenoids content in storage root during development and among varieties and their relationships with major economic traits in orange-fleshed sweetpotato (Ipomoea Batatas (L.) Lam) were studied in present paper.【Method】The dynamics of main economic traits in 15 orange-fleshed sweetpotato varieties on 50, 64, 78, 92, 106, 120, and 134 d after transplanting were investigated, and these traits included the carotenoids content, longest vine length, branches number of vine system, storage roots number, dry matter contents in stem, foliage, petiole and storage roots, fresh and dry weights of storage roots, fresh and dry weights of stem, fresh and dry weights of foliage, fresh and dry weights of aboveground plant, fresh and dry weights of whole plant, and ratios of photosynthate to storage roots, stem, foliage and petiole. The relationship between variations of the carotenoids content and other economic traits during whole developing stage was analyzed. And the relationship between daily growth rates of the carotenoids accumulation and other main economic traits was also analyzed. 【Result】During the whole development, the carotenoids content had three variation types, that is totally leveling, straightly increasing and deviously ascending, and had different responses to the growth of longest vine length, fresh and dry weights of storage roots, photosynthate distributions, and so on. For most of the tested varieties, especially the straightly increasing type in the study, the carotenoids contents had a significant positive correlation with longest vine length, fresh and dry weights of storage roots and ratio of photosynthate to storage roots, and had a significant negative correlation with the ratio of photosynthate to foliage and petiole, however had a least correlation with other traits. Because of the positive correlation between daily growth rates of carotenoids accumulation and fresh and dry weights of storage roots, starch accumulation, soluble sugar accumulation, crude protein accumulation, the carotenoids and dry matter, main nutrient substances accumulated synergistically in storage roots. 【Conclusion】The significant difference and differentiation of carotenoids contents among varieties would take place during development of orange-fleshed sweetpotato, and there were totally leveling, straightly increasing and deviously ascending variation types of carotenoids content because of the synergistical accumulations between carotenoids and dry matter in storage roots among varieties. These variations of carotenoids accumulation had different relationships with main economic traits during development and among varieties in orange-fleshed sweetpotato.

Key words: orange-fleshed sweetpotato , carotenoids , variation types , economic trait , correlationship

后猛, 张允刚, 王欣, 唐维, 刘亚菊, 唐忠厚, 靳容, 闫会, 马代夫, 李强. 橘红肉甘薯块根类胡萝卜素的变化规律及其与主要经济性状的相关性[J]. 中国农业科学, 2013, 46(19): 3988-3996.

HOU Meng, ZHANG Yun-Gang, WANG Xin, TANG Wei, LIU Ya-Ju, TANG Zhong-Hou, JIN Rong, YAN Hui, MA Dai-Fu, LI Qiang. Variation Laws of Carotenoids Content in Storage Root of Orange-Fleshed Sweetpotato and Its Relationships with Major Economic Traits[J]. Scientia Agricultura Sinica, 2013, 46(19): 3988-3996.

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参考文献

[1]Dugas T R, Morel D W, Harrison. Dietary supplementation with β-carotene, but not with lycopene, inhibits endothelial cell-mediated oxidation of low-density lipoprotein. Free RadicalBiology and Medicine, 1999, 26(9/10): 1238-1244.

[2]Bertram J S, Vine A L. Cancer prevention by retinoids and carotenoids: Independent action on a common target. Biochimica et Biophysica Acta, 2005, 1740(2): 170-178.

[3]Naves M M, Silveira E R, Dagli M L, Moreno F S. Effects of beta-carotene and vitamin A on oval cell pro1iferation and connexin 43 expression during hepatic diferentiation in the rat. Journal of Nutritional Biochemistry, 2001, 12(12): 685-692.

[4]Dwyer J H, Navab M, Dwyer K M, Hassan K, Sun P, Shircore A, Hama-Levy S, Hough G, Wang X, Drake T, Merz C N, Fogelman A M. Oxygenated carotenoid lutein and progression of early atherosclerosis: The Los Angeles atherosclerosis study. Circulation, 2001, 103(24): 2922-2927.

[5]Palace V P, Khaper N, Qin Q, Singal P K. Antioxidant potentials of vitamin A and carotenoids and their relevance to heart disease. Free RadicalBiology and Medicine, 1999, 26(5/6): 746-761.

[6]Yamaguchi M, Uchiyama S. Effect of carotenoid on calcium content and alkikine phosphatase activity in rat femoral tissues in vitro: The unique anabolic effect of beta-cryptoxanthin. Biological and Pharmaceutical Bulletin, 2003, 26(8): 1188-1191.

[7]Yamaguchi M, Uchiyama S. Beta-Cryptoxanthin stimulates bone formation and inhibits bone resorption in tissue cu1tures in vitro. Molecular and Cellular Biochemistry, 2004, 258(1/2): 137-144.

[8]González S, Astner S, An W, Goukassian D, Pathak M A. Dietary lutein/zeaxanthin decreases ultraviolet B-induced epidermal hyperproliferation and acute inflammation in hairless mice. Journal of Investigative Dermatology, 2003, 121(2): 399-405.

[9]Lee E H, Faulhaber D, Hanson K M, Ding W, Peters S, Kodali S, Granstein R D. Dietary lutein reduces ultraviolet radiation-induced inflammation and immunosuppression. Journal of Investigative Dermatology, 2004, 122(2): 510-517.

[10]Food and Agriculture Organization (FAO). Agricultural Bulletin Board on Data Collection Dissemination and Quality of Statistics. Available at FAOSTAT Database, 2009. http://apps.fao.org/, Rome, Italy.

[11]谢一芝, 邱瑞镰, 戴起伟, 吴纪中, 张黎玉, 徐品莲. 甘薯胡萝卜素含量的变化及高胡萝卜素育种. 杂粮作物, 1998, 18(4): 43-46.

Xie Y Z, Qiu R L, Dai Q W, Wu J Z, Zhang L Y, Xu P L. Carotene variation of sweet potato and high carotene variety breeding. Rain Fed Crops, 1998, 18(4): 43-46. (in Chinese )

[12]Ben-Amotz A, Levy Y. Bioavailability of a natural isomer mixture compared with synthetic all-trans β-carotene in human serum. American Journal of Clinical Nutrition, 1996, 63(5): 729-734.

[13]Caliskan M E, Sogut T, Boydak E, Erturk E, Arioglu H. Growth, yield, and quality of sweet potato (Ipomoea batatas (L.) Lam.) cultivars in the southeastern anatolian and east mediterranean regions of turkey. Turkish Journal of Agriculture and Forestry, 2007, 31(4): 213-228.

[14]K’osambo L M, Carey E E, Misra A K, Wilkes J, Hagenimana V. Influence of age, farming site, and boiling on pro-vitamin A content in sweet potato (Ipomoea batatas (L.) Lam.) storage roots. Journal of Food Composition and Analysis, 1998, 11(4): 305-321.

[15]Kimura M, Kobori C N, Rodriguez-Amaya D B, Nestel P. Screening and HPLC methods for carotenoids in sweet potato, cassava and maize for plant breeding trials. Food Chemistry, 2007, 100(4): 1734-1746.

[16]孙健, 彭宏祥, 董新红, 朱恩俊, 任娇艳. 甘薯中β-胡萝卜素HPLC测定方法分析. 食品科技, 2009, 34(1): 236-239.

Sun J, Peng H X, Dong X H, Zhu E J, Ren J Y. HPLC analysis method on β-carotene in sweet potato. Food Science and Technology, 2009, 34(1): 236-239. (in Chinese )

[17]陆国权, 黄华宏, 何腾弟. 甘薯维生素C和胡萝卜素含量的基因型、环境及基因型与环境互作效应的分析. 中国农业科学, 2002, 35(5): 482-486.

Lu G Q, Huang H H, He T D. Genotype and environmental effects on vitamin C and carotene contents in sweetpotato. Scientia Agricultura Sinica, 2002, 35(5): 482-486. (in Chinese)

[18]Manrique K, Hermann M. E?ect of G × E interaction on root yield and beta-carotene content of selected sweetpotato [Ipomoea batatas (L.) Lam.] varieties and breeding clones. 2002, CIP Program Report 1999-2000: 281-287.

[19]Mbwaga Z, Mataa M, Msabaha M. Quality and yield stability of orange fleshed sweet potato (Ipomoea batatas) varieties grown in different agro-ecologies//Ahmed K Z. 8th African Crop Science Society Conference. El-Minia, Egypt, 2007: 339-345.

[20]Huang A S, Tanudjaja L, Lum D. Content of alpha-, beta-carotene, and dietary fiber in 18 sweetpotato varieties grown in Hawaii. Journal of Food Composition and Analysis, 1999, 12(2): 147-151.

[21]Teow C C, Truong V D, McFeeters R F, Thompson R L, Pecota K V, Yencho G C. Antioxidant activities, phenolic and β-carotene contents of sweet potato genotypes with varying flesh colours. Food Chemistry, 2007, 103(3): 829-838.

[22]Wu X, Sun C J, Yang L H, Zeng G, Liu Z Y, Li Y M. β-carotene content in sweet potato varieties from China and the effect of preparation on β-carotene retention in the Yanshu No. 5. Innovative Food Science and Emerging Technologies, 2008, 9(4): 581-586.

[23]张小明, 牟德华, 张松树, 马志民. 甘薯中β-胡萝卜素在膨大期的变化规律. 江苏农业科学, 2012, 40(8): 303-305.

Zhang X M, Mu D H, Zhang S S, Ma Z M. Variations of β-carotene content in storage root expansion period of sweetpotato. Jiangsu Agricultural Sciences, 2012, 40(8): 303-305. (in Chinese)

[24]Ma D F, Li Q, Li X Y, Li H M, Tang Z H, Hu L, Cao Q H, Xie Y P, Wang X. Selection of parents for breeding edible varieties of sweetpotato with high carotene content. Scientia Agricultura Sinica, 2009, 8(10): 1166-1173.

[25]唐忠厚, 李洪民, 马代夫. 甘薯蛋白质含量近红外反射光谱分析模型应用研究. 中国食品学报, 2008, 8(4): 169-173.

Tang Z H, Li H M, Ma D F. Studies on the application of analysis model for protein content in sweet potato by near infrared reflectance spectroscopy (NIRS). Journal of Chinese Institute of Food Science and Technology, 2008, 8(4): 169-173. (in Chinese)

[26]李明, 傅玉凡, 王大一, 谭文芳, 杨春贤, 张启堂. 不同肉色甘薯交互嫁接后块根β-胡萝卜素含量的变化.西南农业学报, 2010, 23(2): 462-468.

Li M, Fu Y F, Wang D Y, Tan W F, Yang C X, Zhang Q T. Variations of β-carotene content in sweetpotato [Ipomoea batatas(L.) Lam.] storage roots after reciprocal grafts among 5 varieties with different flesh color. Southwest China Journal Agricultural Sciences, 2010, 23(2): 462-468. (in Chinese)

[27]Lu S, Van Eck J, Zhou X J, Lopez A B, O'Halloran D M, Cosman K M, Conlin B J, Paolillo D J, Garvin D F, Vrebalov J, Kochian L V, Küpper H, Earle E D, Cao J, Li L. The cauliflower Or gene encodes a DnaJ cysteine-rich domain-containing protein that mediates high levels of beta-carotene accumulation. The Plant Cell, 2006, 18(12): 3594-3605.

[28]Desai D P. Understanding the genetic basis of storage root formation along with starch and beta-carotene biosynthesis and their inter-relation in sweetpotato (Ipomoea batatas Lam.). PhD Thesis. Seibersdorf. Austrian Research Centers GmbH –ARC, 2008.