Using a new hybrid rootstock significantly increases the grafted plant rate and watermelon yield
Yan Wang 1,2
Haikun Jiang 1,2,3
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Institute of Horticulture, Anhui Academy of Agricultural Sciences, Hefei 230031 Anhui Province, China
Key Laboratory of Genetic Improvement and Ecophysiology of Horticultural Crops, Hefei 230031 Anhui Province, China
School of Horticulture, Anhui Agricultural University, Hefei 230036 Anhui Province, China
Acceptance date: 2018-08-07
Publication date: 2019-02-14
Int. Agrophys. 2019, 33(1): 97-106
Rootstocks constitute a very important resource of grafted plants, especially in terms of improving the production of watermelon. In this work, a new rootstock, i.e. ‘Wanzhen No. 2’, was used to evaluate the grafting effect on three watermelon cultivars (‘Xiuli’, ‘Jinlvhongling’, and ‘Xinong No. 8’) subjected to double-root-cutting grafting. Protected field trials were also conducted. The obtained results have shown that the double-root-cutting grafting technique significantly increases the root length and dry weight of ‘Wanzhen No. 2’, when compared to bottle gourd rootstock. ‘Wanzhen No. 2’ was also found to significantly increase the average survival rate of grafted seedlings, up to 96% in three experimental bases. The fruits harvested from the ‘Wanzhen No. 2’ grafted plants had higher weight than those obtained from non-grafted plants, without affecting the central sugar content. By using ‘Wanzhen No. 2’ as the rootstock, the water-melon yield significantly improved in ‘Xiuli’ (by 26.7 and 87.4%) and ‘Wanzhen No. 2’ (by 16.3 and 89.2%), when compared to both the control ‘Jiashi’ and the non-grafted plant. The yield of ‘Xinong No. 8’ significantly increased (by 32.2%), when compared to the non-grafted plant. Our study suggests that ‘Wanzhen No. 2’ is a suitable rootstock for grafted seedlings in three watermelon cultivars. We have provided new insights into the rootstock and contributed to the improvement of watermelon grafted plants.
Dorey E., Fournier P., Léchaudel M., and Tixier P., 2016. Modeling sugar content of pineapple under agro-climatic conditions on Reunion Island. Eur. J. Agron., 73, 64-72.
Edelstein M., Tyutyunik J., Fallik E., Meir A., Tadmor Y., and Cohen R., 2014. Horticultural evaluation of exotic watermelon germplasm as potential rootstocks. Sci. Hortic., 165, 196-202.
Hu B., Bennett M.A., and Kleinhenz M.D., 2016. A new method to estimate vegetable seedling vigor, piloted with tomato, for the use in grafting and other contexts. HortTechnol., 26, 767-775.
Huang Y., Jiao Y., Nawaz M.A., Chen C., Liu L., Lu Z., Kong Q., Cheng F., and Bie Z., 2016. Improving the magnesium uptake, photosynthesis and antioxidant enzyme activities of watermelon by grafting onto the pumpkin rootstock under low magnesium. Plant Soil, 409, 229-246.
Huang Y., Tang R., Cao Q., and Bie Z., 2009. Improving the fruit yield and quality of cucumber by grafting onto the salt tolerant rootstock under NaCl stress. Sci Hortic., 122, 26-31.
Huitrón-Ramírez M.V., Ricárdez-Salinas M., and Camacho-Ferre F., 2009. Influence of grafted watermelon plant density on yield and quality in soil infested with a melon necrotic spot virus. HortSci., 44, 1838-1841.
King S.R., Davis A.R., Liu W., and Levi A., 2008. Grafting for disease resistance. HortSci., 43, 1673-1676.
King S.R., Davis A.R., Zhang X., and Crosby K., 2010. Genetics, breeding and selection of rootstocks for Solanaceae and Cucurbitaceae. Sci. Hortic., 127, 106-111.
Kolayli S., Kara M., Tezcan F., Erim F.B., Sahin H., Ulusoy E., and Aliyazicioglu R., 2010. A comparative study of chemical and biochemical properties of different melon cultivars: standard, hybrid and grafted melons. J. Agri. Food Chem., 58, 9764-9769.
Lee JM., Kubota C., Tsao S.J., Bie Z., Echevarria P.H., Morra L., and Oda M., 2010. Current status of vegetable grafting: Diffusion, grafting techniques, automation. Sci. Hortic., 127, 93-105.
Ling G., Shang Q., Len Y., and Zhang Z., 2012. Plug seedling substrate of vegetables. The standard of Agriculture Ministry in China: ICS 65.020.020 B005, NY/T 2118-2012.
Louws F.J., Rivard C.L., and Kubota C., 2010. Grafting fruiting vegetables to manage soil-borne pathogens, foliar pathogens, arthropods and weeds. Sci. Hortic., 127, 127-146.
Lowe I., Cantu D., and Dubcovsky J., 2011. Durable resistance to wheat rusts: integrating systems biology and traditional phenotype-based research methods to guide the deployment of resistance genes. Euphytica, 179, 69-79.
Miguel A., Maroto J.V., San Bautista A., Baixauli C., Cebolla V., Pascual B., López S., and Guardiola J.L., 2004. The grafting of triploid watermelon is an advantageous alternative to soil fumigation by methyl bromide for the control of Fusarium wilt. Sci. Hortic., 103, 9-17.
Mo Y., Wang Y., Yang R., Zheng J., Liu C., Li H., Ma J., Zhang Y., Wei C., and Zhang X., 2016. Regulation of plant growth, photosynthesis, antioxidation and osmosis by an arbuscular mycorrhizal fungus in watermelon seedlings under well-watered and drought conditions. Front. Plant Sci., 7, 1-15.
Mohamed F.H., El-Hamed K.E.A., Elwan M.W.M., and Hussien M.N.E., 2014. Evaluation of different grafting methods and rootstocks in watermelons grown in Egypt. Sci. Hortic., 168, 145-150.
Proietti S., Rouphael Y., Colla G., Cardarelli M., De Agazio M., Zacchini M., Rea E., Moscatello S., and Battistelli A., 2008. Fruit quality of mini-watermelon as affected by grafting and irrigation regimes. J. Sci. Food Agri., 88, 1107-1114.
Reig G., Mestre L., Betrán J.A., Pinochet J., and Moreno M.Á., 2016. Agronomic and physicochemical fruit properties of the ‘Big Top’ nectarine budded on peach and plum based rootstocks in Mediterranean conditions. Sci. Hortic., 210, 85-92.
Ren Y., Di J., Gong G., Zhang H., Guo S., Zhang J., and Xu Y., 2015. Genetic analysis and chromosome mapping of resistance to Fusarium oxysporum f. sp. niveum (FON) race 1 and race 2 in watermelon (Citrullus lanatus L.). Mol. Breeding, 35, 1-9.
Ren Y., Zhao H., Kou Q., Jiang J., Guo S., Zhang H., Hou W., Zou X., Sun H., Gong G., Levi A., and Xu Y., 2012. A high resolution genetic map anchoring scaffolds of the sequenced watermelon genome. Plos One, 7: e29453.
Romano D. and Paratore A., 2001. Effects of grafting on tomato and eggplant. Acta. Hortic., 559, 149-153.
Savvas D., Colla G., Rouphael Y., and Schwarz D., 2010. Amelioration of heavy metal and nutrient stress in fruit vegetables by grafting. Sci. Hortic., 127, 156-161.
Trionfetti N.P., Colla G., Granati E., Temperini O., Crinò P., and Saccardo F., 2002. Rootstock resistance to fusarium wilt, and its effect on fruit yield and quality of two muskmelon cultivars. Sci. Hortic., 93, 281-288.
Turhan A., Ozmen N., Kuscu H., Serbeci M.S., and Seniz V., 2012. Influence of rootstocks on the yield, fruit characteristics and quality of watermelon. Horti. Environ. Biotechnol., 53, 336-341.
Vu N.T., Xu Z.H., Kim Y.S., Kang H.M., and Kim I.S., 2014. Effect of nursery environmental condition and different cultivars on the survival rate of grafted tomato seedlings. Acta. Hortic., 1037, 765-770.
Wang P.C., Fang L., Yan C.S., Jiang H.K., Tian H.M., Wan Y., Zhang J., and Zhang Q.A., 2015. Present situation and countermeasures of grafted seedling production in the Anhui province. Acta. Hortic., 1086, 41-50.
Xing W.W., Li L., Gao P., Li H., Shao Q.S., Shu S., Sun J., and Guo S.R., 2015. Effects of grafting with pumpkin rootstocks on carbohydrate metabolism in cucumber seedlings under Ca(NO3)2 stress. Plant Physiol. Biochem., 87, 124-132.
Yang X., Hu X., Zhang M., Xu J., Ren R., Liu G., Yao X., and Chen X., 2016. Effect of low night temperature on the graft union formation in watermelon grafted onto the bottle gourd rootstock. Sci. Hortic., 212, 29-34.
Yang Y., Lu X., Yan B., Li B., Sun J., Guo S., and Tezuka T., 2013. Bottle gourd rootstock-grafting affects nitrogen metabolism in NaCl-stressed watermelon leaves and enhances short-term salt tolerance. J. Plant Physiol., 170, 653-661.
Yetışır H., Sari N., and Yücel S., 2003. Rootstock resistance to Fusarium wilt and its effect on watermelon fruit yield and quality. Phytoparasitica, 31, 163-169.
Zhu S., Vossen J.H., Bergervoet M., Nijenhuis M., Kodde L., Kessel G.J.T., Vleeshouwers V., Visser R.G.F., and Jacobsen E., 2015. An updated conventional and novel GM potato late blight R gene differential set for virulence monitoring of Phytophthora infestans. Euphytica, 202, 219-234.
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