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Original scientific article

COPPER RESISTANCE OF LAWN GRASS AND CHRYSANTHEMUM CARINATUM PLANTS

By
A. Evgeny Gladkov ,
A. Evgeny Gladkov
Contact A. Evgeny Gladkov

К.А. Timiryazev Institute of Plant Physiology RAS, IPP RAS, Moskow, Russia

I. Ilina Tashlieva ,
I. Ilina Tashlieva

К.А. Timiryazev Institute of Plant Physiology RAS, IPP RAS, Moskow, Russia

V. Olga Gladkova
V. Olga Gladkova

К.А. Timiryazev Institute of Plant Physiology RAS, IPP RAS, Moskow, Russia

Abstract

Condition and quality of the lawn grass and flowering plants is important indicators of the level of landscaping and the urban environment. Copper ions significantly reduce the quality of ornamental plants. The aim of this study was to assess phytotoxicity of copper for Chrysanthemum carinatum, Festuca rubra and Agrostis stolonifera.

High contamination of copper significantly limits the spread of Chrysanthemum carinatum and lawn grass. Chrysanthemum carinatum was less resistant than lawn grass to copper. Chrysanthemum carinatum can grow only with a low level of soil contamination with copper.

References

1.
Gąsiorek M. Heavy metals in soils of Henryk Jordan Park in Krakow. Ecological Chemistry and Engineering. 2011;18:5–6, 697–702.
2.
Overview of the state and environmental pollution in the Russian Federation for 2010. 2011.
3.
Overview of the state and environmental pollution in the Russian Federation for 2014. 2015.
4.
Overview of the state and environmental pollution in the Russian Federation for 2015. 2016.
5.
Overview of the state and environmental pollution in the Russian Federation for 2016. 2017.
6.
Overview of the state and environmental pollution in the Russian Federation for 2017. 2018.
7.
Overview of the state and environmental pollution in the Russian Federation for 2018. 2019.
8.
Report on environment condition of Moscow city in 2015. 2016.
9.
Report on environment condition of Moscow city in 2016. 2017.
10.
Report on environment condition of Moscow city in 2017. 2018.
11.
State report “On the state and Environmental Protection of the Russian Federation in 2016. In: Natural Resources and Environment of the Russian Federation. 2017.
12.
Guralchuk ZZ, Panou-Filotheou H, Bosabalidis AM, Karataglis S. Mechanisms of Plant Resistance to Heavy Metals, Physiology and Biochemistry of Cultivated Plants. Annals of Botany. 1994;26, 2:107–18.
13.
Rasteniya v ekstremal’nykh usloviyakh mineral’nogo pitaniya. Vol. N. V. 1983.
14.
Yruela I. Copper in plants: acquisition, transport and interactions. Funct Plant Biol. 2009;36:409–30.
15.
Cook CM, Kostidou A, Vardaka E, Lanaras T. Effects of copper on the growth, photosynthesis and nutrient concentrations of Phaseolus plants. Vol. 34. 1997. p. 179–93.
16.
Menegaes J, F. B, F. AA, L. B, A. R, Swarowsky A, et al. Evaluation of potential phytoremediation of chrysanthemum in soil with excess copper. Ornamental. 2017;(orticulture,23,1):63-71,.
17.
Daniel S, Ester C. Copper Contamination in Mediterranean Agricultural Soils: Soil Quality Standards and Adequate Soil Management Practices for Horticultural Crops, Soil Contamination – Current Consequences and Further Solutions, Marcelo L. Larramendy and Sonia Soloneski, Intech Open. 2016;10(5772/64771).
18.
V.V A. Study of the resistance of strawberry varieties to the effects of heavy metal salts. In: Materials of the conference “Problems of agroecology and adaptability of varieties in modern horticulture in Russia.” 2008. p. 7–12.
19.
Litvinova II, Gladkov EA, Gladkova ОN. Patent “Method of introduction to the cell culture of Linum perenne.” 2014.
20.
Gladkov EA, Dolgikh Y, O.V G. In vitro selection for tolerance to soil chloride salinization in perennial grasses. Sel’skokhozyaistvennaya Biologiya (Agricultural Biology. 2014;(4):106–11.
21.
Gladkov EA, Dolgikh YI, Gladkova OV. Increasing ecological valence plants to lead. India, Enviro Media: Ecology, Environment and Conservation. 2016;(1):437–40.
22.
Gladkov EA, Tashlieva II, Dolgikh YI, Gladkova OV. Increasing Tolerance Agrostis Stolonifera, Festuca Rubra, Brachycome Iberidifolia, Chrysanthemum Carinatum to Copper. 2019. p. 167–74.
23.
Gladkov EA, Gladkova OV. Increasing Tolerance Plants to Heavy Metals. 2019. p. 159–65.
24.
P. G, G. SSs, A B. Response of in vitro cultures of Nicotiana tabacum L. to copper stress and selection of plants from Cu – tolerant callus // Plant cell tissue and organ culture. Vol. 53. 1998. p. 161–9.
25.
Rout GR, Sahoo S. In vitro selection and plant regeneration of copper-tolerant plants from leaf explants of Nicotiana tabacum L. cv ‘Xanthi’ Plant Breed. 2007;126:403–9.

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