Abstract
The mobility and migration capacity of Zn in the soil-plant system were studied in a series of pot experiments with barley as a test plant. The parameters of Zn accumulation depending on the metal concentrations in soils and soil solutions were estimated by soil and water culture methods. Experiments with barley in water culture were performed on a nutrient (soil) solution extracted from soddy-podzolic soil (Albic Retisol (Loamic, Ochric)) to which Zn2+ was added to reach working concentrations increasing from 0.07 to 430 μM. Different responses of barley plants to changes in the concentration of Zn in the studied soil were identified. Ranges of the corresponding concentrations in the soil and aboveground barley biomass were determined. Parameters of Zn accumulation by test plants were determined depending on the metal content in soddypodzolic soil and the soil solution. A new method was proposed for evaluating the buffer capacity of soils with respect to a heavy metal (Zn) using test plants (BCS(P)Zn). The method was used to evaluate the buffering capacity of loamy sandy soddy-podzolic soil. The considered methodological approach offers opportunities for using data obtained during the agroecological monitoring of agricultural lands with heavy metals (HMs), including the contents of exchangeable HMs and macroelements (C and Mg) in soils and concentrations of HMs and (Ca + Mg) in plants, in the calculation of the buffering capacity of the surveyed soils for HMs.
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References
Agrochemical Methods of Soil Studies (Nauka, Moscow, 1975) [in Russian].
Yu. V. Alekseev, Heavy Metals in Soils and Plants (Agropromizdat, Leningrad, 1987) [in Russian].
V. S. Anisimov, L. N. Anisimova, L. M. Frigidova, D. V. Dikarev, R. A. Frigidov, I. V. Kochetkov, and N. I. Sanzharova, “Evaluation of migration capacity of Zn in the soil–plant system,” Biogeosyst. Techn. 4 (2), 153–163 (2015). doi 10.13187/bgt.2015.4.153. http:// www.ejournal19.com.10.13187/bgt.2015.4.153
V. S. Anisimov, I. V. Kochetkov, D. V. Dikarev, L. N. Anisimova, Yu. N. Korneev, and L. M. Frigidova, “Effect of the physicochemical parameters of soils on the biological availability of natural and radioactive zinc,” Eurasian Soil Sci. 49, 868–878 (2016). doi 10.1134/S1064229316080020
V. S. Anisimov, N. I. Sanzharova, L. N. Anisimova, S. A. Geras’kin, D. V. Dikarev, L. M. Frigidova, R. A. Frigidov, and N. V. Belova, “Evaluation of migration capacity and phytotoxicity of Zn in the soil–plant system,” Agrokhimiya, No. 1, 64–74 (2013).
E. V. Arinushkina, Chemical Analysis of Soils and Grounds (Moscow State Univ., Moscow, 1970) [in Russian].
M. A. Bardyshev, Mineral Nutrition of Potato Plants (Nauka i Tekhnika, Minsk, 1984) [in Russian].
V. N. Bashkin and N. S. Kasimov, Biogeochemistry (Nauchnyi Mir, Moscow, 2004) [in Russian].
I. V. Gulyakin and E. V. Yudintseva, Agricultural Radiobiology (Kolos, Moscow, 1973) [in Russian].
A. W. Galston, P. S. Davis, and R. L. Satter, The Life of the Green Plant (Prentice-Hall, New Jersey, 1980; Mir, Moscow, 1983).
D. V. Dubovik and E. V. Dubovik, “Heavy metals in ordinary chernozems on slopes of different gradients and aspects,” Eurasian Soil Sci. 49, 33–44 (2016). doi 10.1134/S1064229316010051
V. B. Il’in, “Assessment of soil buffer capacity with respect to heavy metals,” Agrokhimiya, No. 10, 109–113 (1995).
A. L. Kovalevskii, Doctoral Dissertation in Geology-Mineralogy (Moscow, 1983).
J. Koolman and K.-H. Röhm, Biochemie mit Vielen Bildern (Thieme, Stuttgart, 1996; Mir, Moscow, 2000).
S. V. Kruglov, V. S. Anisimov, G. V. Lavrent’eva, and L. N. Anisimova, “Parameters of selective sorption of Co, Cu, Zn, and Cd by a soddy-podzolic soil and a chernozem,” Eurasian Soil Sci. 42, 385–393 (2009).
D. V. Ladonin and O. V. Plyaskina, “Mechanisms of Cu(II), Zn(II), Pb(II) sorption by soddy-podzolic soil,” Eurasian Soil Sci. 37, 460–468 (2004).
S. S. Mandzhieva, T. M. Minkina, G. V. Motuzova, S. E. Golovatyi, N. N. Miroshnichenko, N. K. Lukashenko, and A. I. Fateev, “Fractional and group composition of zinc and lead compounds as an indicator of the environmental status of soils,” Eurasian Soil Sci. 47, 511–518 (2014). doi 10.1134/S1064229314050159
S. S. Medvedev, The Plant Physiology (St. Petersburg State Univ., St. Petersburg, 2004) [in Russian].
Methodological Recommendations for Determination of Heavy Metals in Agricultural Soils and Products (Central Scientific Research Institute of Agrochemical Service, Moscow, 1992) [in Russian].
G. V. Motuzova, Compounds of Trace Elements in Soils: System Organization, Ecological Value, and Monitoring (Editorial URSS, Moscow, 1999) [in Russian].
P. H. Nye and P. B. Tinker, Solute Movement in the Soil-Root System (Blackwell, Oxford, 1977; Kolos, Moscow, 1980).
O. V. Nesterova, V. G. Tregubova, and V. A. Semal, “Use of regulatory documents for assessing the contamination of soils with heavy metals, Eurasian Soil Sci. 47, 1161–1166 (2014). doi 10.1134/S1064229314110088
R. I. Pervunina and N. G. Zyrin, “Migration of cadmium compounds in modeled agrobiocenosis,” Proceedings of the Second All-Russia Conference “Migration of Pollutants in Soils and Adjacent Media” (Obninsk, 1978), pp. 182–191.
A. I. Perel’man, Geochemistry of Landscape (Vysshaya Shkola, Moscow, 1975) [in Russian].
D. L. Pinskii, Ion Exchange in Soils (Pushchino, 1997) [in Russian].
Practicum on Agrochemistry, Ed. by V. G. Mineev (Moscow State Univ., Moscow, 2001) [in Russian].
N. L. Rashkovich, “Modeling of mineral nutrition of the plants by regression analysis,” Agrokhimiya, No. 6, 97–106 (1995).
G. Ya. Rin’kis, Kh. K. Ramane, G. V. Paegle, and T. A. Kunitskaya, Optimization System and Diagnostics of Mineral Nutrition of the Plants (Zinatne, Riga, 1989) [in Russian].
T. A. Sokolova, I. I. Tolpeshta, and S. Ya. Trofimov, Soil Acidity. Acid-Base Buffering of Soils. Aluminum Compounds in Solid Phase of Soil and in Soil Solution (Grif i K, Tula, 2012) [in Russian]
T. A. Sokolova and S. Ya. Trofimov, Sorption Properties of Soils. Adsorption. Cation Exchange: Manual on Some Issues of Soil Chemistry (Grif i K, Tula, 2009) [in Russian].
R. A. Frigidov, V. S. Anisimov, L. M. Frigidova, S. A. Geras’kin, L. N. Anisimova, Yu. N. Korneev, and N. I. Sanzharova, “Influence of Zn concentration in soils on accumulation of biomass and metals in the barley plants,” Agrokhimiya, No. 12, 42–54 (2014).
Chemistry of Heavy Metals, Arsenic, and Molybdenum in Soils, Ed. by N. G. Zyrin and L. K. Sadovnikova (Moscow State Univ., Moscow, 1985) [in Russian].
Zinc and Cadmium in the Environment, Ed. by V. V. Dobrovol’skii (Nauka, Moscow, 1992) [in Russian].
N. A. Chernykh, N. Z. Milashchenko, and V. F. Ladonin, Exotoxicological Aspects of Soil Pollution by Heavy Metals (Agrokonsalt, Moscow, 1999) [in Russian].
V. N. Yakimenko and G. A. Konarbaeva, “Transformation of the pool of heavy metals in gray forest soils of agrocenoses,” Agrokhimiya, No. 4, 61–69 (2016).
V. S. Anisimov, I. V. Kochetkov, D. V. Dikarev, L. N. Anisimova, and Y. N. Korneev, “Effects of physical-chemical properties of soils on 60Co and 65Zn bioavailability,” J. Soils Sediments 15 (11), 2232–2243 (2015). doi 10.1007/s11368-015-1153-z
A. J. M. Baker, “Accumulators and excluders—strategies in the response of plants to heavy metals,” J. Plant Nutr. 3, 643–654 (1981). doi 10.1080/01904168109362867
S. A. Barber, Soil Nutrient Bioavailability: A Mechanistic Approach (Wiley, New York, 1995), 2nd ed.
B. C. F. Barbosa, S. C. Silva, R. R. de Oliveira, et al., “Zinc supply impacts on the relative expression of a metallothionein-like gene in Coffea arabica plants,” Plant Soil 411 (1–2), 179–191 (2017). doi 10.1007/ s11104-016-2983-1
P. Beckett, “Potassium-calcium exchange equilibria in soils: specific adsorption sites for potassium,” Soil Sci. 97 (6), 376–383 (1964).
P. H. T. Beckett and M. H. M. Nafady, “Potassium–calcium exchange equilibria in soils: the location of non-specific (Gapon) and specific exchange sites,” J. Soil Sci. 18 (2), 263–281 (1967).
P. H. T. Beckett, “Studies on soil potassium II. The ‘immediate’ Q/I relations of labile potassium in the soil,” J. Soil Sci. 15 (1), 9–23 (1964).
C. Caldelas and D. J. Weiss, “Zinc homeostasis and isotopic fractionation in plants: a review,” Plant Soil 411 (1–2), 17–46 (2017). doi 10.1007/s11104-016-3146-0
C. Cosio, E. Martinoia, and C. Keller, “Hyperaccumulation of cadmium and zinc in Thlaspi caerulescens and Arabidopsis halleri at the leaf cellular level,” Plant Physiol. 134, 716–725 (2004). https://doi.org/10.1104/ pp.103.031948.
H. D. Foth, Fundamentals of Soil Science (Wiley, New York, 1990).
G. Hacisalihoglu and L. V. Kochian, “How do some plants tolerate low levels of soil zinc? Mechanisms of zinc efficiency in crop plants,” New Phytol. 159, 341–350 (2003). doi 10.1046/j.1469-8137.2003.00826.x
G. Hacisalihoglu, J. J. Hart, and L. V. Kochian, “Highand low-affinity zinc transport systems and their possible role in zinc efficiency in bread wheat,” Plant Physiol. 125 (1), 456–463 (2001). https://doi.org/ 10.1104/pp.125.1.456.
J. J. Hart, W. A. Norvell, R. M. Welch, L. A. Sullivan, and L. V. Kochian, “Characterization of zinc uptake, binding, and translocation of bread and durum wheat cultivars,” Plant Physiol. 118 (1), 219–226 (1998). https://doi.org/10.1104/pp.118.1.219
D. L. Jones and P. R. Darrah, “Role of root derived organic acids in the mobilization of nutrients from the rhizosphere,” Plant Soil 166, 247–257 (1994). doi 10.1007/BF00008338
D. L. Jones, A. C. Edwards, K. Donachiei, and P. R. Darrah, “Role of proteinaceous amino acids released in root exudates in nutrient acquisition from the rhizosphere,” Plant Soil 158, 183–192 (1994). doi 10.1007/BF00009493
A. Kabata-Pendias, Trace Elements in Soils and Plants (CRC Press, London, 2011).
Y. F. Lin and M. G. M. Aarts, “The molecular mechanism of zinc and cadmium stress response in plants,” Cell. Mol. Life Sci. 69 (19), 3187–3206 (2012). doi 10.1007/s00018-012-1089-z
X. Liu, J. Chen, G. H. Wang, et al., “Hydrogen sulfide alleviates zinc toxicity by reducing zinc uptake and regulating genes expression of antioxidative enzymes and metallothioneins in roots of the cadmium/zinc hyperaccumulator Solanum nigrum L.,” Plant Soil 400 (1–2), 177–192 (2016). doi 10.1007/s11104-015-2719-7
N. S. Pence, P. B. Larsen, S. D. Ebbs, D. L. D. Letham, M. M. Lasat, D. F. Garvin, D. Eide, and L. V. Kochian, “The molecular physiology of heavy metal transport in the Zn/Cd hyperaccumulator Thlaspi caerulescens,” Proc. Natl. Acad. Sci. U.S.A. 97 (9), 4956–4960 (2000). doi 10.1073/pnas.97.9.4956
K. J. Reddy, L. Wang, and S. P. Gloss, “Solubility and mobility of copper, zinc and lead in acidic environments,” Plant Soil 171, 53–58 (1995). doi 10.1007/ BF00009564
P. N. Sharma, C. Chatterjee, S. C. Agarwala, and C. P. Sharma, “Zinc deficiency and pollen fertility in maize (Zea mays),” Plant Soil 124, 221–225 (1990). doi 10.1007/BF00009263
V. Subhashini, A. V. V. S. Swamy, and R. H. Krishna, “Pot experiment: to study the uptake of zinc by different plant species in artificially contaminated soil,” World J. Environ. Eng. 1 (2), 27–33 (2013). doi 10.12691/wjee-1-2-3
J. Tiong, G. K. McDonald, Y. Genc, et al., “HvZIP7 mediates zinc accumulation in barley (Hordeum vulgare) at moderately high zinc supply,” New Phytol. 201, 131–143 (2014). doi 10.1111/nph.12468
M. Walter, E. Oburger, Y. Schindlegger, S. Hann, M. Puschenreiter, S. M. Kraemer, and W. D. C. Schenkeveld, “Retention of phytosiderophores by the soil solid phase—adsorption and desorption,” Plant Soil 404, 85–97 (2016). doi 10.1007/s11104-016-2800-x
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Original Russian Text © V.S. Anisimov, L.N. Anisimova, L.M. Frigidova, D.V. Dikarev, R.A. Frigidov, Yu.N. Korneev, A.I. Sanzharov, S.P. Arysheva, 2018, published in Pochvovedenie, 2018, No. 4, pp. 427–438.
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Anisimov, V.S., Anisimova, L.N., Frigidova, L.M. et al. Evaluation of the Migration Capacity of Zn in the Soil–Plant System. Eurasian Soil Sc. 51, 407–417 (2018). https://doi.org/10.1134/S1064229318040026
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DOI: https://doi.org/10.1134/S1064229318040026