Scientia Agricultura Sinica ›› 2015, Vol. 48 ›› Issue (19): 3965-3978.doi: 10.3864/j.issn.0578-1752.2015.19.018

• RESEARCH NOTES • Previous Articles     Next Articles

Evolution of Volatile Compounds During the Berry Development of ‘Ruidu Xiangyu’ Grape

ZHANG Ke-kun, WANG Hai-bo, WANG Xiao-di, SHI Xiang-bin, WANG Bao-liang, ZHENG Xiao-cui, LIU Feng-zhi   

  1. Fruit Research Institute, Chinese Academy of Agricultural Sciences/Key Laboratory of Germplasm Resources Utilization of Horticultural Crops, Ministry of Agriculture, Xingcheng 125100, Liaoning
  • Received:2015-04-01 Online:2015-10-01 Published:2015-10-01

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Abstract: 【Objective】 Table grapes with early maturity and fragrant flavors play an important role in fruit industry and are more attractive to consumers when compared with other cultivars. Comprehensive study on the evolution of volatile compounds of early maturing variety is significant for breeding and evaluation of new cultivation technique.【Method】This study used headspace solid phase micro-extraction method and the technology of gas chromatography-mass spectrometry to analyze the changes of volatile compounds and related metabolic pathways of grape berries (V. vinifera cv. Ruidu Xiangyu), which were sampled from 3 weeks to 12 weeks past blossom. In the meantime, the method of PCA was used to clear the relationship between developmental stages and volatile compounds. 【Result】 ‘Ruidu Xiangyu’ came into the stage of verasion at 5 weeks after blossom and into the stage of maturation at 9 weeks after blossom. The fragrant monoterpenes like linalool, nerol, geraniol, citronellol and terpineol accumulated differently at the full developmental process. The maximum content of nerol and geraniol showed up at the beginning of maturation while linalool and terpineol in the middle of it. And the content of citronellol changed irregularly at maturation. E-2-hexenal and hexanal are the main C6 compounds at maturation, and their content went to the peak after verasion and then decreased. Z-3-hexenal mainly existed at young fruit period, of which the content was low at verasion. Additionally, the content of norisoprenoids like β-lonone, damascenone and aromatic compounds like benzaldehyde was very low at maturation. Considering the content change of various compounds, terpenes accumulated differently at different developmental stages and decreased at maturation. Esters mainly accumulated at young fruit period and postveraison stage while aldehydes and ketones were evident at preveraison stage. C6 compounds increased during veraison and then decreased with alcohols. Aromatic compounds and volatile acid accumulated at preveraison and postveraison stage respectively. The key stages for content change are also different to various volatile compounds. Verasion is the key stage for aldehydes and ketones, while major esters and aromatic compounds change before it, and terpenes, C6 compounds and volatile acid change after it. 【Conclusion】Our study indicates that the Z-3-hexenal route from splitting linolenic acid is active at early stage. Other Lipoxygenase (LOX) routes and synthesis of terpenes become active during veraison while accumulations of most compounds become weak at maturity. The key stage for the formation of its characteristic aroma is from verasion to maturity. Major fragrant terpenes accumulate differently in ‘Ruidu Xiangyu’ grape and linalool and α-terpineol decrease later than other monoterpenes. Considering C6 compounds and terpenes, properly delayed harvest will be better for the realization of its fragrance.

Key words: grape, variety with early maturity, volatile compounds, PCA

[1]    Mateo J J, Jiménez M. Monoterpenes in grape juice and wines. Journal of Chromatography A, 2000, 881: 557-567.
[2]    Bueno J E, Peinado R, Moreno J, Medina M, Moyano L, Zea L. Selection of volatile aroma compounds by statistical and enological criteria for analytical differentiation of musts and wines of two grape varieties. Journal of Food Science, 2003, 68: 158-163.
[3]    Oliveira J M, Faria M, Sá F, Barros F, Araújo I M. C6-alcohols as varietal markers for assessment of wine origin. Analytica Chimica Acta, 2006, 563: 300-309.
[4]    Conde C, Silva P, Fontes N, Dias A C P, Tavares R M, Sousa M J, Agasse A, Delrot S, Geros H. Biochemical changes throughout grape berry development and fruit and wine quality. Globe Science Books, 2007, 1(1): 1-22.
[5]    Falcão L D, Revel G D, Perello M C, Moutsiou A, Zanus M C, Bordignon-Luiz M T. A survey of seasonal temperatures and vineyard altitude influences on 2-methoxy-3-isobutylpyrazine, C13- norisoprenoids, and the sensory profile of Brazilian Cabernet Sauvignon wines. Journal of Agricultural and Food Chemistry, 2007, 55(9): 3605-3612.
[6]    Sánchez Palomo E, Diaz-Maroto M C, González Viñas M A, Soriano-Pérez A, Perz-Coello M S. Aroma profile of wines from Albillo and Muscat grape varieties at different stages of ripening. Food Control, 2007, 18: 398-403.
[7]    温可睿, 黄敬寒, 潘秋红, 段长青, 王军. 葡萄香气物质及其影响因素的研究进展. 果树学报, 2012, 29(3): 454-460.
Wen K R, Huang J H, Pan Q H, Duan C Q, Wang J. Research progress of aromatic compounds and influencing factors in grapes. Journal of Fruit Science, 2012, 29(3): 454-460. (in Chinese)
[8]    Vilanova M, Genisheva Z, Bescansa L, Masa A, Oliveira J M. Changes in free and bound fractions of aroma compounds of four Vitis vinifera cultivars at the last ripening stages. Phytochemistry, 2012, 74: 196-205.
[9]    Kalua C M, Boss P K. Evolution of volatile compounds during the development of Cabernet Sauvignon grapes (Vitis vinifera L.). Journal of Agricultural and Food Chemistry, 2009, 57(9): 3818-3830.
[10]   Wilson B, Strauss C R, Williams P J. Changes in free and glycosidically bound monoterpenes in developing Muscat grapes. Journal of Agricultural and Food Chemistry, 1984, 32(4): 919-924.
[11]   Fenoll J, Manso A, Hellín P, Ruiz L, Flores P. Changes in the aromatic composition of the Vitis vinifera grape Muscat Hamburg during ripening. Food Chemistry, 2009, 114(2): 420-428.
[12]   Rocha S, Coutinho P, Barros A, Coimbra M A, Delgadillo I, Cardoso A D. Aroma potential of two Bairrada white grape varieties: Maria Gomes and Bical. Journal of Agricultural and Food Chemistry, 2000, 48(10): 4802-4807.
[13]   Coelho E, Rocha S M, Delgadillo I, Coimbra M A. Headspace-SPME applied to varietal volatile components evolution during Vitis vinifera L. cv.‘Baga’ripening. Analytica Chimica Acta, 2006, 563(1): 204-214.
[14]   穆宁, 张振文, 曹建宏.地形对赤霞珠干红葡萄酒香气成分的影响. 干旱地区农业研究, 2007,25(2): 30-34.
Mu N, Zhang Z W, Cao J H. Influence of different terrain on aroma components of Cabernet Sauvignon dry red wine. Agricultural Research in the Arid Areas, 2007, 25(2): 30-34. (in Chinese)
[15]   王志群, 段长青, 朱保庆, 吴玉文, 涂崔, 潘秋红. 葡萄果实中 (–)–α–萜品醇的积累与其合成酶基因Vvter表达的关系. 园艺学报, 2011, 38(11): 2187-2192.
Wang Z Q, Duan C Q, Zhu B Q, Wu Y W, Tu C. Pan Q H. Relationship between (-)–α–terpineol accumulation and Vvter expression in grape berries. Acta Horticulturae Sinica, 2011, 38(11): 2187-2192. (in Chinese)
[16]   杨晓帆, 高媛, 韩梅梅, 彭振雪, 潘秋红. 云南高原区酿酒葡萄果实香气物质的积累规律. 中国农业科学, 2014, 47(12): 2405-2416.
Yang X F, Gao Y, Han M M, Peng Z X, Pan Q H. Accumulation characteristics of volatile compounds in wine grape berries grown in high altitude regions of Yunnan. Scientia Agricultura Sinica, 2014, 47(12): 2405-2416. (in Chinese)
[17]   Yang C, Wang Y, Wu B, Fang J, Li S. Volatile compounds evolution of three table grapes with different flavour during and after maturation. Food Chemistry, 2011, 128(4): 823-830.
[18]   孙磊, 朱保庆, 孙晓荣, 许晓青, 王晓玥, 张国军, 闫爱玲, 徐海 英. ‘亚历山大’葡萄果实单萜生物合成相关基因转录及萜类物质积累规律. 中国农业科学, 2014, 47(7): 1379-1386.
Sun L, Zhu B Q, Sun X R, Xu X Q, Wang X Y, Zhang G J, Yan A L, Xu H Y. Terpenes biosynthesis related gene transcript profiles and terpenes accunmulation of ‘Alexandria’ grape. Scientia Agricultura Sinica, 2014, 47(7): 1379-1386. (in Chinese)
[19]   Zhang H, Fan P, Liu C, Wu B, Li S, Liang Z. Sunlight exclusion from Muscat grape alters volatile profiles during berry development. Food Chemistry, 2014, 164: 242-250.
[20]   刘崇怀, 潘兴, 郭景南, 樊秀彩, 孔庆山. 葡萄品种浆果成熟期多样性及归类标准评价. 果树学报, 2004, 21(6): 535-539.
Liu C H, Pan X, Guo J N, Fan X C, Kong Q S. Evaluation on the diversity of maturity time of grape cultivars and its classification. Journal of Fruit Science, 2004, 21(6): 535-539. (in Chinese)
[21]   徐海英, 张国军, 闫爱玲. 早熟葡萄新品种‘瑞都香玉’. 园艺学报, 2009, 36(6): 929.
Xu H Y, Zhang G J, Yan A L. A new early maturity grape cultivar ‘Ruidu Xiangyu’. Acta Horticulturae Sinica, 2009, 36(6): 929. (in Chinese)
[22]   Robinson S P, Davies C. Molecular biology of grape berry ripening. Australian Journal of Grape and Wine Research, 2000, 6(2): 175-188.
[23] Selli S, Cabaroglu T, Canbas A, Erten H, Nurgel C. Effect of skin contact on the aroma composition of the musts of Vitis vinifera L. cv. Muscat of Bornova and Narince grown in Turkey. Food Chemistry, 2003, 81(3): 341-347.
[24]   Ribéreau-Gayon, P, Boidron, J N, Terrier A. Aroma of Muscat grape varieties. Journal of Agricultural and Food Chemistry, 1975, 23: 1042-1047.
[25]   Lund S T, Bohlmann J. The molecular basis for wine grape quality-A volatile subject. Science, 2006, 311:804-805.
[26]   Lewinsohn E, Schalechet F, Wilkinson J, Matsui K, Tadmor Y, Nam K H, Amar O, Lastochkin E, Larkov O, Ravid U, Hiatt W,Gepstein S, Pichersky E. Enhanced levels of the aroma and flavor compound S-linalool by metabolic engineering of the terpenoid pathway in tomato fruits. Plant Physiology, 2001, 127(3): 1256-1265.
[27]   Lücker J, Bouwmeester H J, Schwab W, Blaas J, Plas L H W. Verhoeven H A. Expression of Clarkia S‐linalool synthase in transgenic petunia plants results in the accumulation of S-linalyl-β- d-glucopyranoside. The Plant Journal, 2001, 27(4): 315-324.
[28]   房经贵, 刘崇怀. 葡萄分子生物学. 北京: 科学出版社, 2014: 76-99.
Fang J G, Liu C H. Grape Molecular Biology. Beijing: Science Press, 2014: 76-99. (in Chinese)
[29]   Podolyan A, White J, Jordan B, Winefield C. Identification of the lipoxygenase gene family from Vitis vinifera and biochemical characterisation of two 13-lipoxygenases expressed in grape berries of Sauvignon Blanc. Functional Plant Biology, 2010, 37(8): 767-784.
[30]   Matsui K. Green leaf volatiles: hydroperoxidelyase pathway of oxylipin metabolism. Current Opinion in Plant Biology, 2006, 9(3): 274-280.
[31]   Zhu B Q, Xu X Q, Wu Y W, Duan C Q, Pan Q H. Isolation and characterization of two hydroperoxidelyase genes from grape berries. Molecular Biology Reports, 2012, 39(7): 7443-7455.
[32]   Tesnière C, Verriès C. Molecular cloning and expression of cDNAs encoding alcohol dehydrogenases from Vitis vinifera L. during berry development. Plant Science, 2000, 157(1): 77-88.
[33]   Beekwilder J, Alvarez-Huerta M, Neef E, Verstappen F W A. Bouwmeester H J, Aharoni A. Functional characterization of enzymes forming volatile esters from strawberry and banana. Plant Physiology, 2004, 135(4): 1865-1878.
[34]   Mathieu S, Terrier N, Bigey F, Gunata Z. A carotenoid cleavage dioxygenase from Vitis vinifera L.: functional characterization and expression during grape berry development in relation to C13- norisoprenoid accumulation. Journal of Experimental Botany, 2005, 56(420): 2721-2731.
[35]   Gil M, Bottini R, Berli F, Pontin M, Silva M F, Piccoli P. Volatile organic compounds characterized from grapevine (Vitis vinifera L. cv. Malbec) berries increase at pre-harvest and in response to UV-B radiation. Phytochemistry, 2013, 96: 148-157.
[36]   Deluc L G, Quilici D R, Decendit A, Grimplet J, Wheatley M D, Schlauch K A, Merillon J M, Cushman J C, Cramer G R. Water deficit alters differentially metabolic pathways affecting important flavor and quality traits in grape berries of Cabernet Sauvignon and Chardonnay. BMC Genomics, 2009, 10(1): 212.
[37]   Bindon K A, Dry P R, Loveys B R. Influence of plant water status on the production of C13-norisoprenoid precursors in Vitis vinifera L. cv. Cabernet Sauvignon grape berries. Journal of Agricultural and Food Chemistry, 2007, 55(11): 4493-4500.
[38]   Bravdo B A. Effect of cultural practices and environmental factors on fruit and wine quality. Agriculturae Conspectus Scientificus, 2001, 66(1): 13-20.
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