ACCUMULATION OF HEAVY METALS IN THE VEGETATIVE ORGANS OF POPLARS UNDER THEIR JOINT INTRODUCTION TO THE SOIL
DOI: http://dx.doi.org/10.30970/sbi.1804.798
Abstract
Background. Studies of plant autecology under excessive heavy metal intake require a thorough understanding of the specifics of the uptake and accumulation of these substances by plants. It is therefore important to study the redistribution of heavy metals in the soil–plant system. Poplars, due to their rapid growth, large assimilative organ surface area, etc., are a suitable object for studying their autecological properties and potential use in the creation of green spaces.
Materials and methods. The objects of the study were two-year-old poplar seedlings: ’I-45/51’, ’Lvivska’, ’Robusta’, ’Tronco’, and the soils on which they grow. The plants were watered once a week for 2 months with a mixture of heavy metal compounds at 1, 5, and 10 maximum permissible concentrations (MPC). Mixtures of the following salts were used as heavy metal sources CdSO4, Ni(NO3)2, CuSO4, ZnSO4, Pb(CH3COO)2. The control plants were not exposed to heavy metals. All plants were grown under natural light and temperature. The content of mobile forms of Cu, Zn, Ni, Pb, and Cd in ammonium acetic acid extract from soil was determined and their accumulation in leaves and roots was measured by conventional methods using a C-115PK atomic absorption spectrophotometer Selmi (Ukraine). Statistical processing of the results was carried out using Microsoft Excel 2013. To assess the probability of the difference between the statistical characteristics of two alternative data sets, a univariate analysis of variance using IBM SPSS Statistics 27, ANOVA, was performed.
Results. The accumulation and translocation of heavy metals in the soil–plant system was studied in model experiments. The study revealed the peculiarities of heavy metal accumulation in the soils where poplars grew. It was shown that the introduction of heavy metal compounds leads to an increase in the content of mobile forms of the studied elements in the soil. Under the influence of 1, 5, and 10 MPC of heavy metal ions, all cultivars accumulated them more actively in the root system than in the leaves.
Conclusions. The studied poplars can be divided into two groups. The first one includes the cultivars ’I-45/51’ and ’Lvivska’ with a high level of heavy metal accumulation and the highest enrichment factor. The second group – ’Tronco’ and ’Robusta’ – includes those with low levels of heavy metal accumulation and low enrichment factors. The results suggest that the poplars of the second group have physiological mechanisms that determine the observed peculiarities of heavy metal translocation.
Keywords
Full Text:
PDFReferences
| Adler, A., Karacic, A., Wästljung, A.-C. R., Johansson, U., Liepins, K., Gradeckas, A., & Christersson, L. (2021). Variation of growth and phenology traits in poplars planted in clonal trials in Northern Europe - implications for breeding. BioEnergy Research, 14(2), 426-444. doi:10.1007/s12155-021-10262-8 Crossref ● Google Scholar | ||||
| ||||
| Agbemafle, R., Elsie Aggo, S., Akutey, O., & Bentum, J. K. (2020). Heavy metal concentrations in leachates and crops grown around waste dumpsites in Sekondi-Takoradi in the Western Region of Ghana. Research Journal of Environmental Toxicology, 14(1), 16-25. doi:10.3923/rjet.2020.16.25 Crossref ● Google Scholar | ||||
| ||||
| Barman, S. C., Sahu, R. K., Bhargava, S. K., & Chaterjee, C. (2000). Distribution of heavy metals in wheat, mustard, and weed grown in field irrigated with industrial effluents. Bulletin of Environmental Contamination and Toxicology, 64(4), 489-496. doi:10.1007/s001280000030 Crossref ● PubMed ● Google Scholar | ||||
| ||||
| Bessonova, V., & Grytsay, Z. (2018). Content of plastid pigments in the needles of Pinus pallasiana D. Don in different forest growth conditions of anti-erosion planting. Ekológia (Bratislava), 37(4), 338-344. doi:10.2478/eko-2018-0025 Crossref ● Google Scholar | ||||
| ||||
| Bi, X., Feng, X., Yang, Y., Qiu, G., Li, G., Li, F., Liu, T., Fu, Z., & Jin, Z. (2006). Environmental contamination of heavy metals from zinc smelting areas in Hezhang County, western Guizhou, China. Environment International, 32(7), 883-890. doi:10.1016/j.envint.2006.05.010 Crossref ● PubMed ● Google Scholar | ||||
| ||||
| Cabinet of Ministers of Ukraine. (2021). Pro zatverdzhennia normatyviv hranychno dopustymykh kontsentratsii nebezpechnykh rechovyn u gruntakh, a takozh pereliku takykh rechovyn [On approval of standards for maximum permissible concentrations of hazardous substances in soils, as well as a list of such substances]. Kyiv, "Uryadovy Courier". 243. Retrieved from https://zakon.rada.gov.ua/laws/show/1325-2021-%D0%BF#Text (In Ukrainian) | ||||
| ||||
| Danylchuk, O., Danylchuk, N., Boyko, L., & Yukhymenko, Y. (2023). The influence of heavy metal pollution on the pigment content in the assimilation apparatus of poplar cultivars in the conditions of the Iron Ore region. Ekológia (Bratislava), 42(4), 319-326. doi:10.2478/eko-2023-0035 Crossref ● Google Scholar | ||||
| ||||
| Dhiman, R. C., Arunachalam, A., Dhyani, S. K., Singh, A., Kumar, R., Biradar, C. M., & Rizvi, J. (2024). Circular economy of poplar-based agroforestry in India. Indian Journal of Agroforestry, 26(1), 12-22. Retrieved from https://www.cifor-icraf.org/publications/pdf_files/articles/ADhiman-2024.pdf Google Scholar | ||||
| ||||
| Gryshko, V. M., Syshchykov, D. V., Piskova, O. M., Danilchuk, O. V., & Mashtaler, N. V. (2012). Vazhki metaly: nadkhodzhennia v grunty, translokatsiia u roslynakh ta ekolohichna bezpeka [Heavy metals: entering to soil, translocation in plants and ecological danger]. Donetsk: Donbas. (In Ukrainian) Google Scholar | ||||
| ||||
| Gupta, S., Nayek, S., Saha, R. N., & Satpati, S. (2007). Assessment of heavy metal accumulation in macrophyte, agricultural soil, and crop plants adjacent to discharge zone of sponge iron factory. Environmental Geology, 55(4), 731-739. doi:10.1007/s00254-007-1025-y Crossref ● Google Scholar | ||||
| ||||
| He, J., Ma, C., Ma, Y., Li, H., Kang, J., Liu, T., Polle, A., Peng, C., & Luo, Z.-B. (2013). Cadmium tolerance in six poplar species. Environmental Science and Pollution Research, 20(1), 163-174. doi:10.1007/s11356-012-1008-8 Crossref ● PubMed ● Google Scholar | ||||
| ||||
| Hrytsaenko, Z. M., Hrytsaenko, A. O., & Karpenko, V. P. (2003). Metody biolohichnykh ta ahrokhimichnykh doslidzhen roslyn i gruntiv [Methods of biological and agrochemical studies of plants and soils]. Kyiv: Nichlava. (In Ukrainian) Google Scholar | ||||
| ||||
| Guralchuk, Zh. Z. (2006). Fitotoksychnist vazhkykh metaliv ta stiikist roslyn do yikh dii [Phytotoxicity of heavy metals and plant resistance to their effects]. Kyiv: Logos. (In Ukrainian) Google Scholar | ||||
| ||||
| Guralchuk, Zh. Z., & Gudkov, I. M. (2005). Phytoremediation and its role in soil cleaning from heavy metals and radionuclides. Physiology and Biochemistry of Cultivated Plants, 37(5), 371-383. (In Ukrainian) Google Scholar | ||||
| ||||
| ISO. (2018). Soil quality - Sampling Part 203: investigation of potentially contaminated sites (ISO Standard No. ISO 18400-203:2018). Geneva: International Organization for Standardization. Retrieved from https://www.iso.org/standard/65226.html | ||||
| ||||
| Kabata-Pendias, A. (2010). Trace elements in soils and plants. 4th edn. Boca Raton: CRC Press. doi:10.1201/b10158 Crossref ● Google Scholar | ||||
| ||||
| Kisku, G. C., Barman, S. C., & Bhargava, S. K. (2000). Contamination of soil and plants with potentially toxic elements irrigated with mixed industrial effluent and its impact on the environment. Water, Air, & Soil Pollution, 120, 121-137. doi:10.1023/a:1005202304584 Crossref ● Google Scholar | ||||
| ||||
| Kochmar, I., & Karabyn, V. (2022). Investigation of deportment of chalcophilic heavy metals in the waste rock of central coal enrichment plant "Chervonohradska" for the purposes of environmental safety of Lviv-Volyn coal basin. Journal Environmental Problems, 7(4), 169-176. doi:10.23939/ep2022.04.169 Crossref ● Google Scholar | ||||
| ||||
| Kort, J., & Schroeder, W. (Eds.). (2020). Activities related to the cultivation and utilization of poplars, willows and other fast-growing trees in Canada 2016-2019. Canadian Report to the International Commission on Poplars and Other Fast-Growing Trees Sustaining People and the Environment 26th Session. Rome, Italy. Retrieved from http://www.poplar.ca/upload/documents/ipccan2020.pdf | ||||
| ||||
| Kutsokon, N., Rakhmetov, D., Rakhmetova, S., Khudolieieva, L., & Rashydov, N. (2022). Nursery screening of poplar and willow clones for biofuel application in Ukraine. IForest -Biogeosciences and Forestry, 15(5), 401-410. doi:10.3832/ifor3732-015 Crossref ● Google Scholar | ||||
| ||||
| Langhof, M., & Schmiedgen, A. (2023). 13 years of biomass production from three poplar clones in a temperate short-rotation alley cropping agroforestry system. Biomass and Bioenergy, 175, 106853. doi:10.1016/j.biombioe.2023.106853 Crossref ● Google Scholar | ||||
| ||||
| Levenets, T. V., Smirnov, O. E., Taran, N. Yu., Mykhalska, L. M., & Schwartau, V. V. (2022). Cadmium stress in plants: toxicity and resistance mechanisms. Plant Physiology and Genetics, 54(4), 279-310. doi:10.15407/frg2022.04.279 (In Ukrainian) Crossref ● Google Scholar | ||||
| ||||
| Lv, F., Shan, Q., Qiao, K., Zhang, H., & Zhou, A. (2023). Populus euphratica plant cadmium resistance 2 mediates Cd tolerance by root efflux of Cd ions in poplar. Plant Cell Reports, 42, 1777-1789. doi:10.1007/s00299-023-03065-y Crossref ● PubMed ● Google Scholar | ||||
| ||||
| Mareri, L., Parrotta, L., & Cai, G. (2022). Environmental stress and plants. International Journal of Molecular Sciences, 23(10), 5416. doi:10.3390/ijms23105416 Crossref ● PubMed ● PMC ● Google Scholar | ||||
| ||||
| Masiuk, O., Novitskyi, R., Hapich, H., & Chubchenko, Y. (2023, October). Elements of assessment of the anthropogenic impact of a coal mining mine on the site of the Emerald Network using methods of remote sensing of the Earth. In: International Conference of Young Professionals "GeoTerrace-2023" (Vol. 2023, No. 1, pp. 1-5). European Association of Geoscientists & Engineers. doi:10.3997/2214-4609.2023510007 Crossref ● Google Scholar | ||||
| ||||
| Michopoulos, P. (2021). Nickel in forests - a short review on its distribution and fluxes. Folia Oecologica, 48(2), 205-214. doi:10.2478/foecol-2021-0021 Crossref ● Google Scholar | ||||
| ||||
| Mirko, L., & Volker, S. (2024). Poplars and other fast-growing tree species in Germany: report of the National Poplar Commission 2020-2023 (No. 237a) Thünen Working Papers, Johann Heinrich von Thünen Institute, Federal Research Institute for Rural Areas, Forestry and Fisheries. Retrieved from https://literatur.thuenen.de/digbib_extern/dn068120.pdf Google Scholar | ||||
| ||||
| Pant, M., Dolma, S., Gahlot, M., Sharma, A., & Mundepi, S. (2023). Phytoremediation of heavy metals. In: R. P. Singh, P. Singh, A. Srivastava (Eds.), Heavy metal toxicity: environmental concerns, remediation and opportunities (pp. 313-340). Springer, Singapore. doi:10.1007/978-981-99-0397-9_15 Crossref ● Google Scholar | ||||
| ||||
| Ramlan, Basir-Cyio, M., Napitupulu, M., Inoue, T., Anshary, A., Mahfudz, Isrun, Rusydi, M., Golar, Sulbadana, & Bakri, R. (2021). Pollution and contamination level of Cu, Cd, and Hg heavy metals in soil and food crop. International Journal of Environmental Science and Technology, 19(3), 1153-1164. doi:10.1007/s13762-021-03345-8 Crossref ● Google Scholar | ||||
| ||||
| Savosko, V. M., Bielyk, Y. V., Lykholat, Y. V., & Heilmeier, H. (2022). Assesment of heavy metals concentration in initial soils of post-mining landscapes in Kryvyi Rih District (Ukraine). Ekológia (Bratislava), 41(3), 201-211. doi:10.2478/eko-2022-0020 Crossref ● Google Scholar | ||||
| ||||
| Sharma, A., Kapoor, D., Gautam, S., Landi, M., Kandhol, N., Araniti, F., Ramakrishnan, M., Satish, L., Singh, V. P., Sharma, P., Bhardwaj, R., Tripathi, D. K., & Zheng, B. (2022). Heavy metal induced regulation of plant biology: recent insights. Physiologia Plantarum, 174(3). doi:10.1111/ppl.13688 Crossref ● PubMed ● Google Scholar | ||||
| ||||
| Singh, R., Singh, D. P., Kumar, N., Bhargava, S. K., & Barman, S. C. (2010). Accumulation and translocation of heavy metals in soil and plants from fly ash contaminated area. Journal of Environmental Biology, 31(4), 421-430. Retrieved from https://www.jeb.co.in/journal_issues/201007_jul10/paper_07.pdf Google Scholar | ||||
| ||||
| Tan, L., Qu, M., Zhu, Y., Peng, C., Wang, J., Gao, D., & Chen, C. (2020). Zinc transporter5 and zinc transporter9 function synergistically in zinc/cadmium uptake. Plant Physiology, 183(3), 1235-1249. doi:10.1104/pp.19.01569 Crossref ● PubMed ● PMC ● Google Scholar | ||||
| ||||
| Thevs, N., Fehrenz, S., Aliev, K., Emileva, B., Fazylbekov, R., Kentbaev, Y., Qonunov, Y., Qurbonbekova, Y., Raissova, N., Razhapbaev, M., & Zikirov, S. (2021). Growth rates of poplar cultivars across Central Asia. Forests, 12(3), 373. doi:10.3390/f12030373 Crossref ● Google Scholar | ||||
| ||||
| Welham, S. J., Gezan, S. A., Clark, S. J., & Mead, A. (2014). Statistical methods in biology: design and analysis of experiments and regression. CRC Press, Boca Raton, FL. doi:10.1201/b17336 Crossref ● Google Scholar | ||||
| ||||
| Zadorozhnaya, G. A., Andrusevych, K. V., & Zhukov, O. V. (2018). Soil heterogeneity after recultivation: ecological aspect. Folia Oecologica, 45(1), 46-52. doi:10.2478/foecol-2018-0005 Crossref ● Google Scholar | ||||
| ||||
| Zhang, X., Yang, M., Yang, H., Pian, R., Wang, J., & Wu, A.-M. (2024). The uptake, transfer, and detoxification of cadmium in plants and its exogenous effects. Cells, 13(11), 907. doi:10.3390/cells13110907 Crossref ● PubMed ● PMC ● Google Scholar | ||||
Refbacks
- There are currently no refbacks.
Copyright (c) 2024 Оleksandr Danylchuk, Vitalii Gryshko, Lyudmyla Boyko, Nataliia Danylchuk
This work is licensed under a Creative Commons Attribution 4.0 International License.