Research Article
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Year 2022, Volume: 39 Issue: 2, 120 - 128, 31.08.2022
https://doi.org/10.55507/gopzfd.1088185

Abstract

Supporting Institution

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References

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  • Alengebawy, A., Abdelkhalek, S. T., Qureshi, S. R., & Wang, M.-Q. (2021). Heavy metals and pesticides toxicity in agricultural soil and plants: Ecological risks and human health implications. Toxics, 9(3), 42.
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  • Anjum, N. A., Umar, S., Ahmad, A., & Iqbal, M. (2008). Responses of components of antioxidant system in moongbean genotypes to cadmium stress. Communications in soil science and plant analysis, 39(15-16), 2469-2483.
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  • Bavaresco, L., Giachino, E., & Pezzutto, S. (2003). Grapevine rootstock effects on lime‐induced chlorosis, nutrient uptake, and source–sink relationships. Journal of plant nutrition, 26(7), 1451-1465.
  • Borchard, N., Siemens, J., Ladd, B., Möller, A., & Amelung, W. (2014). Application of biochars to sandy and silty soil failed to increase maize yield under common agricultural practice. Soil and Tillage Research, 144, 184-194.
  • Borges, K. L. R., Hippler, F. W. R., Carvalho, M. E. A., Nalin, R. S., Matias, F. I., & Azevedo, R. A. (2019). Nutritional status and root morphology of tomato under Cd-induced stress: comparing contrasting genotypes for metal-tolerance. Scientia Horticulturae, 246, 518-527. Bremner, J. (1965). Total nitrogen. Methods of Soil Analysis: Part 2 Chemical and Microbiological Properties, 9, 1149-1178.
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  • Chaffei, C., Pageau, K., Suzuki, A., Gouia, H., Ghorbel, M. H., & Masclaux-Daubresse, C. (2004). Cadmium toxicity induced changes in nitrogen management in Lycopersicon esculentum leading to a metabolic safeguard through an amino acid storage strategy. Plant and cell physiology, 45(11), 1681-1693.
  • Cheng, K., Tian, H., Zhao, D., Lu, L., Wang, Y., Chen, J., Liu, X., Jia, W., & Huang, Z. (2014). Atmospheric emission inventory of cadmium from anthropogenic sources. International Journal of Environmental Science and Technology, 11(3), 605-616.
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Determination of Grapevine Rootstocks Resistancy to Cadmium (Cd) Toxicity

Year 2022, Volume: 39 Issue: 2, 120 - 128, 31.08.2022
https://doi.org/10.55507/gopzfd.1088185

Abstract

In this study, response of 12 grapevine rootstock genotypes to cadmium (Cd) toxicity were investigated. The Cd application to the soil was made at the beginning of the experiment at 4 different (0, 5, 10 ve 20 mg Cd kg-1) doses. Shoot, leaf and root dry matter yields, leaf Cd, N, P and Zn contents were determined to assess genotype tolerance of Cd toxicity. Present findings revealed that based on shoot, leaf and root dry weights, leaf Cd, N, P and Zn contents, there were Cd-sensitive and resistant genotypes among the present ones. At the greatest Cd dose (Cd20), the greatest Cd contents (µg plant-1) were observed in 8B (6.13), 420A (5.35) and 1103P (4.69) rootstocks and the lowest Cd contents were observed in 99R (1.27) and SO4 (1.58) rootstocks. Among the grapevine rootstocks, SO4 with quite lower leaf Cd accumulation than the other genotypes and increasing shoot and leaf dry weights and leaf N, P and Zn content was identified as resistant against toxic Cd conditions. On the other hand, 8B, 420A, 1103P, 5BB, Harmony genotypes with decreasing shoot, leaf and root dry weights under Cd toxicity conditions, higher leaf Cd accumulations and significantly decreasing leaf N, P and Zn contents were considered as sensitive to Cd toxicity.

References

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  • Angelova, V. R., Ivanov, A. S., & Braikov, D. M. (1999). Heavy metals (Pb, Cu, Zn and Cd) in the system soil–grapevine–grape. Journal of the Science of Food and Agriculture, 79(5), 713-721.
  • Anjum, N. A., Umar, S., Ahmad, A., & Iqbal, M. (2008). Responses of components of antioxidant system in moongbean genotypes to cadmium stress. Communications in soil science and plant analysis, 39(15-16), 2469-2483.
  • Anwar, S., Khan, S., Ashraf, M. Y., Noman, A., Zafar, S., Liu, L., Ullah, S., & Fahad, S. (2017). Impact of chelator-induced phytoextraction of cadmium on yield and ionic uptake of maize. International journal of phytoremediation, 19(6), 505-513.
  • Bavaresco, L., Giachino, E., & Pezzutto, S. (2003). Grapevine rootstock effects on lime‐induced chlorosis, nutrient uptake, and source–sink relationships. Journal of plant nutrition, 26(7), 1451-1465.
  • Borchard, N., Siemens, J., Ladd, B., Möller, A., & Amelung, W. (2014). Application of biochars to sandy and silty soil failed to increase maize yield under common agricultural practice. Soil and Tillage Research, 144, 184-194.
  • Borges, K. L. R., Hippler, F. W. R., Carvalho, M. E. A., Nalin, R. S., Matias, F. I., & Azevedo, R. A. (2019). Nutritional status and root morphology of tomato under Cd-induced stress: comparing contrasting genotypes for metal-tolerance. Scientia Horticulturae, 246, 518-527. Bremner, J. (1965). Total nitrogen. Methods of Soil Analysis: Part 2 Chemical and Microbiological Properties, 9, 1149-1178.
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  • Cakmak, I., Welch, R., Erenoglu, B., Römheld, V., Norvell, W., & Kochian, L. (2000). Influence of varied zinc supply on re-translocation of cadmium (109Cd) and rubidium (86Rb) applied on mature leaf of durum wheat seedlings. Plant and Soil, 219(1), 279-284.
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  • Cheng, K., Tian, H., Zhao, D., Lu, L., Wang, Y., Chen, J., Liu, X., Jia, W., & Huang, Z. (2014). Atmospheric emission inventory of cadmium from anthropogenic sources. International Journal of Environmental Science and Technology, 11(3), 605-616.
  • Chun, C.-P., Zhou, W., Ling, L.-L., Cao, L., Fu, X.-Z., Peng, L.-Z., & Li, Z.-G. (2020). Uptake of cadmium (Cd) by selected citrus rootstock cultivars. Scientia Horticulturae, 263, 109061.
  • El Rasafi, T., Oukarroum, A., Haddioui, A., Song, H., Kwon, E. E., Bolan, N., Tack, F. M., Sebastian, A., Prasad, M., & Rinklebe, J. (2021). Cadmium stress in plants: A critical review of the effects, mechanisms, and tolerance strategies. Critical Reviews in Environmental Science and Technology, 1-52.
  • Erdem, H. (2021). The effects of biochars produced in different pyrolsis temperatures from agricultural wastes on cadmium uptake of tobacco plant. Saudi Journal of Biological Sciences, 28(7), 3965-3971.
  • Erdem, H., Kinay, A., Günal, E., Yaban, H., & Tutuş, Y. (2017). The effects of biochar application on cadmium uptake of tobacco. Carpathian Journal of Earth and Environmental Sciences, 12(2).
  • Erdem, H., Kınay, A., Ozturk, M., & Tutus, Y. (2012). Effect of cadmium stress on growth and mineral composition of two tobacco cultivars. Journal of Food, Agriculture & Environment, 10(1), 965-969.
  • Genchi, G., Sinicropi, M. S., Lauria, G., Carocci, A., & Catalano, A. (2020). The effects of cadmium toxicity. International journal of environmental research and public health, 17(11), 3782.
  • Gouia, H., Ghorbal, M. H., & Meyer, C. (2000). Effects of cadmium on activity of nitrate reductase and on other enzymes of the nitrate assimilation pathway in bean. Plant Physiology and Biochemistry, 38(7-8), 629-638.
  • Goyal, D., Yadav, A., Prasad, M., Singh, T. B., Shrivastav, P., Ali, A., Dantu, P. K., & Mishra, S. (2020). Effect of heavy metals on plant growth: an overview. Contaminants in agriculture, 79-101.
  • Grant, C. A., Buckley, W. T., Bailey, L. D., & Selles, F. (1998). Cadmium accumulation in crops. Canadian Journal of Plant Science, 78(1), 1-17. https://doi.org/10.4141/p96-100
  • Greger, M., & Löfstedt, M. (2004). Comparison of uptake and distribution of cadmium in different cultivars of bread and durum wheat. Crop Science, 44(2), 501-507. Haider, F. U., Coulter, J. A., Cheema, S. A., Farooq, M., Wu, J., Zhang, R., Shuaijie, G., & Liqun, C. (2021). Co-application of biochar and microorganisms improves soybean performance and remediate cadmium-contaminated soil. Ecotoxicology and Environmental Safety, 214, 112112.
  • Hart, J. J., Welch, R. M., Norvell, W. A., Sullivan, L. A., & Kochian, L. V. (1998). Characterization of cadmium binding, uptake, and translocation in intact seedlings of bread and durum wheat cultivars. Plant physiology, 116(4), 1413-1420.
  • He, J., Zhou, J., Wan, H., Zhuang, X., Li, H., Qin, S., & Lyu, D. (2020). Rootstock–scion interaction affects cadmium accumulation and tolerance of malus. Frontiers in Plant Science, 11, 1264.
  • Hussain, B., Ashraf, M. N., Abbas, A., Li, J., & Farooq, M. (2021). Cadmium stress in paddy fields: effects of soil conditions and remediation strategies. Science of The Total Environment, 754, 142188.
  • Hussain, T., Murtaza, G., Ghafoor, A., & Cheema, M. A. (2016). The Cd: Zn ratio in a soil affects Cd toxicity in spinach (Spinacea oleracea L.). Pak. J. Agri. Sci, 53(2), 419-424. Ibacache, A. G., & Sierra, C. B. (2009). Influence of rootstocks on nitrogen, phosphorus and potassium content in petioles of four table grape varieties. Chilean Journal of Agricultural Research, 69(4), 503-508.
  • Kacar, B., & İnal, A. (2008). Bitki analizleri (Vol. No: 1241). Nobel Yayın.
  • Kaya, C., Okant, M., Ugurlar, F., Alyemeni, M. N., Ashraf, M., & Ahmad, P. (2019). Melatonin-mediated nitric oxide improves tolerance to cadmium toxicity by reducing oxidative stress in wheat plants. Chemosphere, 225, 627-638.
  • Khurana, M., & Jhanji, S. (2014). Influence of cadmium on dry matter yield, micronutrient content and its uptake in some crops. Journal of Environmental biology, 35(5), 865.
  • Kim, S., Chang, A., Page, A., & Warneke, J.(1988). Relative concentrations of cadmium and zinc in tissue of selected food plants grown on sludge‐treated soils (0047-2425).
  • Kinay, A., Erdem, H., & Karakoç, E. (2021). Chemical Composition of Tobacco Genotypes in Response to Zinc Application Under Cadmium Toxicity. Romanian Agricultural Research, 38, 301-310.
  • Lecourt, J., Lauvergeat, V., Ollat, N., Vivin, P., & Cookson, S. J. (2015). Shoot and root ionome responses to nitrate supply in grafted grapevines are rootstock genotype dependent. Australian Journal of Grape and Wine Research, 21(2), 311-318.
  • Lin, Y.-F., & Aarts, M. G. (2012). The molecular mechanism of zinc and cadmium stress response in plants. Cellular and molecular life sciences, 69(19), 3187-3206.
  • Loi, N., Sanzharova, N., Shchagina, N., & Mironova, M. (2018). The effect of cadmium toxicity on the development of lettuce plants on contaminated sod-podzolic soil. Russian Agricultural Sciences, 44(1), 49-52.
  • Lugon-Moulin, N., Zhang, M., Gadani, F., Rossi, L., Koller, D., Krauss, M., & Wagner, G. (2004). Critical review of the science and options for reducing cadmium in tobacco (Nicotiana tabacum L.) and other plants. Advances in agronomy, 83(1), 111-118.
  • Luo, Z.-B., He, J., Polle, A., & Rennenberg, H. (2016). Heavy metal accumulation and signal transduction in herbaceous and woody plants: paving the way for enhancing phytoremediation efficiency. Biotechnology Advances, 34(6), 1131-1148.
  • Miklós, E., & Erdei, L. (1997). Effect of cadmium on growth and ion transport of grapevine. V International Symposium on Grapevine Physiology 526
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There are 65 citations in total.

Details

Primary Language English
Subjects Agricultural Engineering (Other)
Journal Section Research Articles
Authors

Rüstem Cangi 0000-0002-8264-9844

Halil Erdem 0000-0002-3296-1549

Banu Kılıç 0000-0002-6392-7271

Publication Date August 31, 2022
Published in Issue Year 2022 Volume: 39 Issue: 2

Cite

APA Cangi, R., Erdem, H., & Kılıç, B. (2022). Determination of Grapevine Rootstocks Resistancy to Cadmium (Cd) Toxicity. Journal of Agricultural Faculty of Gaziosmanpaşa University (JAFAG), 39(2), 120-128. https://doi.org/10.55507/gopzfd.1088185