Investigating the Relationship between Soil Acidity and Some Quality Characteristics of Tea Green Leaves in Tea Plantations of Gilan Province

Document Type : Research Paper

Authors

1 Faculty member Tea Research Center, Horticultural Science Research Institute, AREEO, Lahijan, Iran - Former student of University of Tabriz

2 Department of Soil Science, College of Agriculture,University of Tabriz , Tabriz, Iran

Abstract

Tea is a permanent and evergreen plant that grows adeptly in acidic soils. The tea plant naturally absorbs aluminum and accumulates it in various shoot parts. Although aluminum is essential for tea growth, it is harmful to human health. Evaluating aluminum status in both soils and tea green leaves is necessary to better understand their relationships in order to improve the quality as well as quantity of tea yields. For this purpose, 38 samples of the soils and the third green leaves of tea (as an index leaf) were collected randomly from tea plantations of Guilan Province. In soil samples, besides the general properties, the values of pHw, pHCaCl2, exchangeable aluminum, calcium and magnesium, total nitrogen and available concentrations of phosphorus and potassium were determined. Concentrations of the aforementioned nutrients along with iron and zinc were also evaluated in the tea leaves. Based on the results, the mean values of pHw and pHCaCl2, and the mean concentrations of soil exchangeable aluminum and leaf aluminum were 4.51, 4.04, 256 mg/kg, and 1362 mg/kg, respectively. The soil exchangeable aluminum had inverse power relationships with pHw and pHCaCl2 with the coefficients of determination of 66% and 84%, respectively. This indicated that the pHCaCl2 was more valid than pHw. Leaf Al concentration showed no significant correlation with soil pH, but had significant relationship with soil exchangeable aluminum (r=0.69**). Furthermore, the total polyphenol content of the green tea leaves had no significant correlation with leaf Al concentration, but had significant relationship with (Al/(Fe+Zn)) ratio in tea leaves (r=0.64***). According to the lower limit of optimum pH for tea plantations (pH=4.5), the maximum permissible concentration of soil exchangeable aluminum was estimated to be 153 mg/kg. In order to control soil exchangeable aluminum and adjusting soil pH, it is recommended to use lime or dolomite, based on the soil buffering capacity.

Keywords

Main Subjects

References

  1. Al-Baquy, M. A., Li, J.-Y., Xu, C.-Y., Mehmood, K., and Xu, R.-K. 2017. Determination of critical pH and Al concentration of acidic Ultisols for wheat and canola crops. Solid Earth, 8(1): 149-159.
  2. Bahrami, A., Emadodin, I., Ranjbar Atashi, M., and Rudolf Bork, H. 2010. Land-use change and soil degradation: A case study, North of Iran. Agriculture and Biology Journal of North America, 1(4): 600-605.
  3. Bandyopadhyay, S., Dutta, D., Chattopadhyay, T., Reza, S. K., Dutta, D. P., Baruah, U. and Singh, S. K. 2014. Characterization and classification of some tea-growing soils of Jorhat district, Assam. Agropedology, 24(2): 138-145.
  4. Beretta, A. N., Silbermann, A. V., Paladino, L., Torres, D., Bassahun, D., Musselli, R., and García-Lamohte, A. (2014). Soil texture analyses using a hydrometer: Modification of the Bouyoucos method. Ciencia e Investigación Agraria, 41(2): 263-271.
  5. Bertsch, P. M., and Bloom, P. R. 1996. Aluminum. p. 517-550. In D. L. Sparks (ed.) Methods of soil analysis. Part 3. Third edition. Chemical Methods. ASA and SSSA, Madison, WI.
  6. Bremner, J. M. 1996. Total Nitrogen. p. 1149-1178. In D. L. Sparks (ed.) Methods of soil analysis. Part 3. Chemical methods. Third edition. ASA and SSSA, Madison, WI.
  7. Cao, H. L., Cai, F. Y., Jiao, W.-B., Liu, C., Zhang, N., Qiu, H.-Y. and Lü, J. 2018. Assessment of tea garden soils at An'xi County in southeast China reveals a mild threat from contamination of potentially harmful elements. Royal Society Open Science, 5(8): 180050.
  8. Conyers, M. K., and Davey, B. G. J. S. S. 1988. Observations on some routine methods for soil pH determination. Soil Science, 145(1): 29-36.
  9. Darvishi-Foshtomi, M., Norouzi, M., Rezaei, M., Akef, M., and Akbarzadeh, A. 2011. Qualitative and economic land suitability evaluation for tea (Camellia sinensis) in sloping area of Guilan, Iran. Journal of Biological Environmental Sciences, 5(15): 135-146.
  10. Dengiz, O., Sekan, İ., Saygin, F., and İmamoğlu, A. 2020. Assessment of soil quality index for tea cultivated soils in Ortaçay micro catchment in Black Sea region. Journal of Agricultural Sciences, 26(1): 42-53.
  11. Ding, Z. J., Shi, Y. Z., Li, G. X., Harberd, N. P., and Zheng, S. J. 2021. Tease out the future: How tea research might enable crop breeding for acid soil tolerance. Plant Communications, 2(3), 100182.
  12. Enesi, R. O., Dyck, M., Chang, S., Thilakarathna, M. S., Fan, X., Strelkov, S., and Gorim, L. Y. 2023. Liming remediates soil acidity and improves crop yield and profitability - a meta-analysis. Frontiers in Agronomy, 5:1194896.
  13. Erdemoǧlu, S. B., Pyrzyniska, K., and Güçer, Ş. 2000. Speciation of aluminum in tea infusion by ion-exchange resins and flame AAS detection. Analytica Chimica Acta, 411: 81.
  14. Fageria, N.K. Ballgar, V.C., and Wright, R.J. 1988. Aluminum toxicity in crop plants. Journal of Plant Nutrition, 11(3): 309-319.
  15. Fang, X.-M., Chen, F.-S., Hu, X.-F., Yuan, P.-C., Li, J., and Chen, X. 2014. Aluminum and nutrient interplay across an age-chronosequence of tea plantations within a hilly red soil farm of subtropical China. Soil Science and Plant Nutrition, 60(4): 448-459.
  16. Frankowski, M., Ziola-Frankowska, A., and Siepak, J. 2013. From soil to leaves-Aluminum fractionation by single step extraction procedures in polluted and protected areas. Journal of Environmental Management, 127:1-9.
  17. Hajiboland, R. 2017. Environmental and nutritional requirements for tea cultivation. Folia Horticulturae, 29(2): 199-220.
  18. Hajiboland, R., Barceló, J., Poschenrieder, C., and Tolrà, R. 2013. Amelioration of iron toxicity: A mechanism for aluminum-induced growth stimulation in tea plants. Journal of Inorganic Biochemistry, 128: 183-187.
  19. Hajiboland, R., Moradi, A., Kahneh, E., Poschenrieder, C., Nazari, F., Pavlovic, J., Nikolic, M. 2023. Weed species from tea gardens as a source of novel aluminum hyperaccumulators. Plants, 12(11): 2129.
  20. Hajimahmoodi, H., Hanifeh, M., Oveisi, M., Sadeghi, N., and Janat, B. 2008. Determination of total antioxidant capacity of green teas by the ferric reducing/antioxidant power assay. Journal of Environmental Health Science and Engineering. 5(3): 167-172.
  21. Hamid, F., Ahmad, T., Waheed, A., Ahmad, N., and Aslam, S. 2014. Effect of different levels of nitrogen on the chemical composition of tea ( sinensis L.) grown at higher altitude. Journal of Materials and Environmental Science, 5(1): 37-80.
  22. Han, T., Cai, A., Liu, K., Huang, J., Wang, B., Li, D., Qaswar, M., Feng, G., and Zhang, H. 2019. The links between potassium availability and soil exchangeable calcium, magnesium, and aluminum are mediated by lime in acidic soil. Journal of Soils and Sediments, 19 (3):1382-1392.
  23. Horst, W. J., Wang, Y., and Eticha, D. 2010. The role of the root apoplast in aluminium-induced inhibition of root elongation and in aluminium resistance of plants: a review. Annals of Botany, 106(1): 185-197.
  24. Huang, W., Lin, M., Liao, J., Li, A., Tsewang, W., Chen, X., and Zheng, P. 2022. Effects of potassium deficiency on the growth of tea (Camelia sinensis) and strategies for optimizing potassium levels in soil: A critical review. Horticulturae, 8(7): 660.
  25. Helmke, P. A., & Sparks, D. L. 1996. Lithium, sodium, potassium, rubidium, and cesium. p. 551-574. In D. L. Sparks (ed.). Methods of soil analysis. Part 3. Chemical methods ASA and SSSA, Madison, WI.
  26. Hosseinikhah-Choshali, A., Seraji, A., Rezaee, S., and Shirinfekr, A. 2013. The relationship between soil pH and population level of Pratylenchus loosi in tea plantations of Iran. Archives of phytopathology and plant protection, 46(12): 1384-1392.
  27. Hu, X.-F., Chen, F.-S., Wine, M. L., and Fang, X.-M. 2017. Increasing acidity of rain in subtropical tea plantation alters aluminum and nutrient distributions at the root-soil interface and in plant tissues. Plant and Soil, 417(1): 261-274.
  28. Jiang, Y., Yang, X., Ni, K., Ma, L., Shi, Y., Wang, Y., Ruan, J. 2023. Nitrogen addition reduces phosphorus availability and induces a shift in soil phosphorus cycling microbial community in a tea (Camellia sinensis L.) plantation. Journal of Environmental Management, 342, 118207.
  29. Jones Jr, J.B. 2001. Laboratory guide for conducting soil tests and plant analysis. CRC Press.
  30. Kahneh, E., Shirinfekr, A., Ramzi, S., and Salimi, K. M. 2022. Effects of long-term tea (Camellia sinensis) cultivation on the earthworm populations in northern Iran. Eurasian Journal of Soil Science, 11(3): 234-240.
  31. Khormali, F., Foomani, F. K., and Fatemi, A. 2012. Tea yield and soil properties as affected by slope position and aspect in Lahijan area, Iran. International Journal of Plant Production, 1(1): 99-111.
  32. Kome, G. K., Enang, R. K., Yerima, B. P. K., and Lontsi, M. G. R. 2018. Models relating soil pH measurements in H2O, KCl and CaCl2 for volcanic ash soils of Cameroon. Geoderma Regional, 14: e00185.
  33. Kuo, S. 1996. Phosphorus. p. 869-919. In D. L. Sparks (ed.) Methods of soil analysis. Part 3. Chemical methods. Third edition. ASA and SSSA, Madison, WI.
  34. Li, S., Li, H., Yang, C., Wang, Y., Xue, H., and Niu, Y. 2016. Rates of soil acidification in tea plantations and possible causes. Agriculture, Ecosystems and Environment, 233: 60-66.
  35. Lierop, W.V. 1981. Conversion of organic soil pH values measured in water, 0.01M CaCl2 or 1N KCl. Canadian Journal of Soil Science, 61: 577-579.
  36. Liu, H., Zhu, R., Shu, K., Lv, W., Wang, S., and Wang, C. 2022. Aluminum stress signaling, response, and adaptive mechanisms in plants. Plant Signaling and Behavior, 17(1): 2057060.
  37. Ma, L., Zhu, Y., Geng, S., Ruan, J. 2022. Response of nutritional status and tea quality to the rate and substitution of chemical fertilizers with organic manure. Horticulturae, 8:1198.
  38. Malakar, H., Timsina, G., Dutta, J., Borgohain, A., Deka, D., Babu, A., Paul, R.K., Yeasin, M., Rahman, F.H., Panja, S. and Karak, T. 2022. Sick or rich: Assessing the selected soil properties and fertility status across the tea-growing region of Dooars, West Bengal, India. Frontiers in Plant Science. 13:1017145.
  39. Manrique, L. A. 1986. The relationship of soil pH to aluminum saturation and exchangeable aluminum in ultisols and oxisols. Communications in Soil Science and Plant Analysis, 17(4): 439-455.
  40. Mehmood, K., Li, J.-Y., Jiang, J., Shi, R.-Y., Liu, Z.-D., and Xu, R.-K. 2017. Amelioration of an acidic ultisol by straw-derived biochars combined with dicyandiamide under application of urea. Environmental Science and Pollution Research, 24(7): 6698-6709.
  41. Miller, R.O. and Kissel, D.E. 2010. Comparison of soil pH methods on soils of north America. Soil Science Society America Journal, 74: 310-316.
  42. Minasny, B., McBratney, A. B., Brough, D. M., and Jacquier, D. 2011. Models relating soil pH measurements in water and calcium chloride that incorporate electrolyte concentration. European Journal of Soil Science, 62(5): 728-732.
  43. Muhammad, N., Zvobgo, G., and Zhang, G.-P. 2019. A review: The beneficial effects and possible mechanisms of aluminum on plant growth in acidic soil. Journal of Integrative Agriculture, 18: 1518–1528.
  44. Mukhopadyay, M., Bantawa, P., Das, A., Sarkar, B., Bera, B., Ghosh, P., and Mondal, T. K. 2012. Changes of growth, photosynthesis and alteration of leaf antioxidative defence system of tea [Camellia sinensis (L.) O. Kuntze] seedlings under aluminum stress. BioMetals, 25(6): 1141-1154.
  45. Mukherjee M., Chakraborty S., Sarkar S., Saha S., Majumder S., Ghosh A., and Bhattacharya M. 2020. Soil Nutritional Status of Tea Plantations in Plains of Sub Himalayan West Bengal, Indian. Current Agriculture Research Journal, 8(3): 239-246.
  46. Nelson, D. W., and Sommers, L. E. 1996. Total carbon, organic carbon, and organic matter. p. 961-1010. In D. L. Sparks (ed.), Methods of soil analysis. Part 3. Chemical methods. Third edition. ASA and SSSA, Madison, WI.
  47. Oh, K., Kato, T., Li, Z.-P., and Li, F.-Y. 2006. Environmental problems from tea cultivation in Japan and a control measure using calcium cyanamide. Pedosphere, 16(6): 770-777.
  48. Pansu, M., and Gautheyrou, J. 2007. Handbook of soil analysis: Mineralogical, organic and inorganic methods. Springer, Berlin.
  49. Peng, A., Yu, K., Yu, S., Li, Y., Zuo, H., Li, P., Li, J., Huang, J., Liu, Z., and Zhao, J. 2023. Aluminum and fluoride stresses altered organic acid and secondary metabolism in tea (Camellia sinensis) Plants: Influences on plant tolerance, tea quality and safety. International Journal of Molecular Sciences, 24(5):4640.
  50. Prawira-Atmaja, M. I., Shabri, Khomaini, H. S., Maulana, H., Harianto, S., and Rohdiana, D. 2018. Changes in chlorophyll and polyphenols content in Camellia sinensis sinensisat different stage of leaf maturity. IOP Conference Series: Earth and Environmental Science, 131(1):012010.
  51. Roozitalab, M. H., Siadat, H., and Farshad, A. 2018. The soils of Iran. World soils book series. Springer Cham.
  52. Ruan, J., Ma, L., Shi, Y., and Zhang, F. 2004. Effects of litter incorporation and nitrogen fertilization on the contents of extractable aluminium in the rhizosphere soil of tea plant (Camallia sinensis (L.) O. Kuntze). Plant and Soil, 263(1): 283-296.
  53. Ruan, J., Ma, L., and Shi, Y.2006. Aluminium in tea plantations: mobility in soils and plants, and the influence of nitrogen fertilization. Environmental Geochemistry and Health, 28(6): 519-528.
  54. Ruan, J., Ma, L., and Shi, Y. 2013. Potassium management in tea plantations: Its uptake by field plants, status in soils, and efficacy on yields and quality of teas in China. Journal of Plant Nutrition and Soil Science, 176(3): 450-459.
  55. Safaei-Chaeikar, S., Marzvan, S., Jahangirzadeh Khiavi, S., and Rahimi, M. 2020. Changes in growth, biochemical, and chemical characteristics and alteration of the antioxidant defense system in the leaves of tea clones (Camellia sinensis) under drought stress. Scientia Horticulturae, 265: 109257.
  56. Shirinfekr, A., Oustan, S., Najafi, N., and Reyhanitabar, A. 2022. Morphological and biochemical responses of some promising tea genotypes to aluminum-induced soil acidification. International Journal of Horticultural Science and Technology, 9(4): 463-476.
  57. Singleton, V. L., Orthofer, R., and Lamuela-Raventós, R. M. 1999. Analysis of total phenols and other oxidation substrates and antioxidants by means of folin-ciocalteu reagent. p.152-178. In L. Packer (ed.) Methods in Enzymology,Vol. 299. Academic Press.
  58. Street, R., Drabek, O., Szakova, J., and Mladkova, L. 2007. Total content and speciation of aluminium in tea leaves and tea infusions. Food Chemistry, 104(4): 1662-1669.
  59. Stumpe, J. M., and Vlek, P. L. G. 1991. Acidification induced by different nitrogen sources in columns of selected tropical soils. Soil Science Society of America Journal, 55(1): 145-151.
  60. Thomas, G. W. 1996. Soil pH and soil acidity. p. 475-490. In D. L. Sparks (ed.) Methods of soil analysis. Part 3. Chemical Methods. Third edition. ASA and SSSA, Madison, WI.
  61. Tolrà, R., Martos, S., Hajiboland, R., and Poschenrieder, C. 2020. Aluminium alters mineral composition and polyphenol metabolism in leaves of tea plants (Camellia sinensis). Journal of Inorganic Biochemistry, 204:110956.
  62. Tong, D., and Xu, R. 2012. Effects of urea and (NH4)2SO4 on nitrification and acidification of Ultisols from Southern China. Journal of Environmental Sciences, 24(4): 682-689.
  63. Uwiragiye Y., Ngaba M.J.Y., Yang M., Elrys A.S., Chen Z., and Zhou J. 2023. Spatially explicit soil acidification under optimized fertilizer use in sub-Saharan Africa. Agronomy, 13(3):632.
  64. Walna, B., Spychalski, W., and Siepak, J. 2005. Assessment of potentially reactive pools of aluminium in poor forest soils using two methods of fractionation analysis. Journal of Inorganic Biochemistry, 99(9): 1807-1816.
  65. Wang, H., Xu, R.-K., Wang, N., and Li, X.-H. 2010. Soil acidification of Alfisols as influenced by tea cultivation in eastern China. Pedosphere, 20(6): 799-806.
  66. Wei, K., Liu, M., Shi, Y., Zhang, H., Ruan, J., Zhang, Q., and Cao, M. 2022. Metabolomics reveal that the high application of phosphorus and potassium in tea plantation inhibited amino-acid accumulation but promoted metabolism of flavonoid. Agronomy, 12(5):1086.
  67. Willson, K. C., and Clifford, M. N. 2012. Tea: Cultivation to consumption: Chapman and Hall, London, p. 792.
  68. Yan, P., Wu, L., Wang, D., Fu, J., Shen, C., Li, X., and Wen-yan, H. 2020. Soil acidification in Chinese tea plantations. Science of the Total Environment, 715: 136963.
  69. Yang, Y., Liu, Y., Huang, C.-F., de Silva, J., and Zhao, F.-J. 2016. Aluminium alleviates fluoride toxicity in tea (Camellia sinensis). Plant and Soil, 402, 179–190.
  70. Yu, J., Xia, L., Yin, D., and Zhou, C. 2018. Effects of phosphorus on aluminum tolerance of Chinese fir seedlings. Scientia Silvae Sinicae, 54(5): 36-47.
  71. Zhang, J., Yang, R., Chen, R., Peng, Y., Wen, X., and Gao, L. 2018. Accumulation of heavy metals in tea leaves and potential health risk assessment: A case study from Puan County, Guizhou Province, China. International Journal of Environmental Research and Public Health, 15(1):133.
Iranian Journal of Soil Research
Volume 37, Issue 3
December 2023
Pages 259-276

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