References
- Abduloyeva, O.S., Karpenko, N.I. 2012. Justification of invasiveness criteria for alien plant species in Ukraine. Chornomorski Botanic Journal, 8 (3), 252–256.
- Belgard, A.L. 1971. Steppe Forestry. Forestry Industry, Moscow.
- Bessonova, V., Grytsay, Z. 2018. Content of plastid pigments in the needles of Pinus pallasiana D. Don in different forest growth conditions of antierosion planting. Ecológia, 37 (4), 338–344. DOI: 10.2478/eco-2018-0025
- Bessonova, V.P., Jusypiva, Y.I. 2018. Morpho-anatomical parameters of the needles of Pinus pallasiana D. Don in different forest growth conditions of antierosion afforestation (in Ukrainian). Ukrainian Journal of Ecology, 8 (1), 851–858. DOI: 10.1542/2017.285
- Bessonova, V.P., Kuchma, V.N., Nemchenko, M.V. 2015. Comparative characteristics of Pallas pine at different levels of the slope of the ravine in anti-erosion plantations. Actual problems, current state, innovations in the field of environmental management and construction. Blagoveshchensk, Far Eastern State Agriculture University, 44–49.
- Bessonova, V.P., Zaytseva, I.A., Nemchenko, M.V. 2017. Dendroflora of the «Voyskovaya Balka» stow (Dnipropetrovsk Region). Phytodiversity of Eastern Europe, 2, 70–77.
- Brunner, I., Herzog, C., Dawes, M.A., Arend, M., Sperisen, Ch. 2013. How tree roots respond to drought. Frontiers Plant Science, 29, 1–16. DOI: 10.3389/fpls.2015.00547
- Chaves, M.M., Flexas, J., Pinheiro, C. 2009. Photo-synthesis under drought and salt stress: regulation mechanisms from whole plant to cell. Annals of Botany, 103 (4), 551–560. DOI: 10.1093/aob/mcn125
- Couee, I., Sulmon C., Gouesbet, G., El Amrani, A. 2006. Involvement of soluble sugars in reactive oxygen species balance and response to oxidative stress in plants. Journal of Experimental Botany, 57 (3), 449–459. DOI: 10.1093/jxb/erj027
- Dubenok, N.N., Tanyukevich, V.V., Salogub, R.W., Kulik, A.V. 2017. The state and meliorative influence of field-free forest residents in the conditions of the steppe Crimea. Izvestia of the Lower Volga Agro-University Complex, 4 (48), 16–21.
- Gruber, A., Pirkebner, D., Oberhuber, W. 2013. Seasonal dynamics of mobile carbohydrate pools in phloem and xylem of two alpine timberline conifers. Tree Physiology, 33 (10), 1076–1083. DOI: 10.1093/tree-phys/tpt088
- Hare, P.D., Cress, W.A., van Staden J. 1998. Dissecting the roles of osmolyte accumulation during stress. Plant Cell and Environment, 21, 535–553. DOI: 10.1046/j.1365-3040.1998.00309.x
- Kameli, A., Lösel, D.M. 1993. Carbohydrates and water status in wheat plants under water stress. New Phytologist, 125, 609–614.
- Karimova, I.S., Ergashev, A., Abdullaev, A. 2008. The influence of soil drought on the carbohydrate content in different cotton sorts and lines. Bulletin of the Academy of Sciences of the Republic of Tajikistan, 2 (163), 31–36.
- Kaur, G., Asthir, B. 2015. Proline: a key player in plant abiotic stress tolerance. Biologia Plantarum, 59 (4), 609–619. DOI: 10.1007/s10535-015-0549-3
- Kiriziy, D.A., Veselovska, L.I., Kots, S.Ya. 2014. The influence of drought on gas exchange of leaves of soybean inoculated by rhizobia under seed lectin application. Plant Physiology and Genetics, 46 (6), 498–506.
- Kolupaev, Y.E., Ryabchun, N.I., Vayner, A.A. 2015. Antioxidant enzyme activity and osmolyte content in winter cereal seedlings under hardening and cryostress. Plant Physiology, 62 (4), 533–541.
- Kolupaev, Y.E., Trunova, T.I. 1992. Metabolism and protective functions of plant carbohydrates under stress. Physiology and Biochemistry of Cultivated Plants, 24 (6), 523–532.
- Korshikov, I.I., Krasnoshtan, O.V., Terlyga, N.S., Mazur, A.E. 2005. Natural renewal of Pinus pallasiana D. Don on a iron ore dump in Kriviy Rig region. Introduction of Plant, 28 (4), 46–51. DOI: 10.5281/zenodo.2584227
- Korshikov, I.I., Lapteva, E.V. 2014. Pollen of Pinus pallasiana (Pinaceae) from plantings of environmentally safe and technogenically contaminated lands of the steppe zone of Ukraine. Ukrainian Botanical Journal, 71 (5), 590–598. DOI: 10.15407/ukrbotj71.05.590
- Korshikov, I.I., Terlyga, N.S. 2008. Genetic peculiarities of Pinus pallasiana D. Don trees with high and low rate of ovule pollination in artifical stands of Kriviy Rig. Introduction of Plant, 37, 32–37. DOI 10.5281/zenodo.2556932
- Korytova, A.I., Mikhailov, O.F., Bessonova, V.P. 1976. The content of pigments and carbohydrate metabolism in the needles of Scots pine depending on the growing conditions. Questions of steppe forestry and nature protection. Proceedings of the Complex Expedition of Dnepropetrovsk State University: collection of scientific articles of Dnepropetrovsk State University (ed. A.L. Belgard). DSU, Dnepropetrovsk, 94–99.
- Korzh, O.P., Dubovik, O.S., Dubova, O.V. 2016. The state of Pinus pallasiana under the condition of city Zaporizhzhya. Current Issues of Biology, Ecology and Chemistry, 11 (1), 67–81.
- Kotlikoff, L.D., Kazakova, M.V., Nesterova, K.V. 2017. Problem of global warming and consequences of a struggle with it for the Russian economy. Russian Journal of Entrepreneurship, 18 (4), 633–640.
- Krasnoshtan, O.V. 2016. Formation population of Crimean pine (Pinus pallasiana D. Don) on Iron Ore Dumps of Kryvorizhzhya. Scientific Bulletin of UNFU, 26 (5), 67–73. DOI: 10.15421/40260509
- Krasnoshtan, O.V. 2017. Vitality of Pinus pallasiana D. Don. and P. sylvestris L. in iron ore dumps of Kryvyi Rih area. Introduction of Plant, 74, 73–79. DOI: 10.5281/zenodo.2300398
- Kruchkov, S.N, Kireeva, O.V. 2015. The experience of introducing the species of pine (Pinus) in the lower Volga region. Science Journal of Volgograd State University, 3 (13), 18–28. DOI: 10.15688/jvolsu11.2015.3.2
- Kulik, A.V., Gordienko, O.A., Pugacheva, A.M., Voronina, V.P., Uzolin, A.I. 2019. Scientific basis for creation of a natural monument on the ravine-beam lands of the right bank of the Don in order to preserve the unique silvicultural complexes. Izvestia of the Lower Volga Agro-University Complex, 4 (56), 100–110. DOI: 10.32786/2071-9485-2019-04-11
- Kulik, K.N., Semenyutina, A.V. 2010. Enrichment of forest-melioration complexes with introduction resources. Izvestia of the Lower Volga Agro-University Complex, 1 (17), 1–9.
- Kursanov, A.L. 1976. Transport of assimilates in a plant. Science, Moscow.
- Lapteva, E.V. 2016. The Influence of technogenic pollution of Kryvorizhzhya Environment on pollen quality of Pinus sylvestris L. and P. pallasiana D. Don. Scientific Bulletin of UNFU, 26 (5), 204–209. DOI: 10.15421/40260531
- Lawlor, D.W, Tezara, W. 2009. Causes of decreased photosynthetic rate and metabolic capacity in water-deficient leaf cells: a critical evaluation of mechanisms and integration of processes. Annals of Botany, 103 (4), 561–579. DOI: 10.1093/aob/mcn244
- Lawlor, D.W., Cornic, G. 2002. Photosynthetic carbon assimilation and associated metabolism in relation to water deficits in higher plants. Plant Cell and Environment, 25, 275–294. DOI: 10.1046/j.0016-8025.2001.00814.x
- Levin, S.V., Pashchenko, V.I. 2018. Bioecological peculiarities of introduction of Pallas pine format on the territory of the centrally black soil region of Russia. Forestry Information, 4, 74–90. DOI: 10.24419/LHI.2304-3083.2018.4.08
- Levin, S.V., Semenov, M.A., Pashchenko, V.I., Levin, I.S. 2019. Environmental features of Crimean pine growth with joint growth with Scots pine. Forestry Engineering Journal, 1, 44–53. DOI: 10.12737/article_5c92016cce31d2.57961318
- Maevskaya, S.N., Nikolaeva, M.K. 2013. Response of antioxidant and osmoprotective systems of wheat seedlings to drought and rehydration. Russian Journal of Plant Physiology, 60 (3), 351–359.
- Matsevityi, Yu.M., Shubenko, A.L., Kanilo, P.M., Solovey, V.V. 2016. Energy, ecology, and globalclimate warming. Reports of the National Academy of Sciences of Ukraine, 12, 102–107.
- Mohammadkhani, N., Heidari, R. 2008. Drought-induced accumulation of soluble sugars and proline in two maize varieties. World Applied Sciences Journal, 3 (3), 448–453.
- Nikolaeva, M.K., Maevskaya, S.N., Voronin, P.Y. 2015. Activities of antioxidant and osmoprotective systems and photosynthetic gas exchange in maize seedlings under drought conditions. Russian Journal of Plant Physiology, 62 (3), 340–346.
- Nikolaeva, M.K., Maevskaya, S.N., Voronin, P.Y. 2017. Photosynthetic CO2/H2O gas exchange and dynamics of carbohydrates content in maize leaves under drought. Russian Journal of Plant Physiology, 64 (4), 277–284.
- Novitskaya, Yu.E. 1971. Features of physiological and biochemical processes in needles and spruce shoots in the north. Nauka, Moscow.
- Pochinok, H.N. 1976. Methods of biochemical analysis of plants. Naukova Dumka, Kiev.
- Povorotnia, M.M. 2015. Features of carbohydrate metabolism of maples at different conditions of technogenic load in the steppe Prydniprov’ia. Issues of Steppe Forestry and Forest Reclamation of Soils, 44, 138–145.
- Reddy, A.R., Chaitanya, K.V., Vivekanandan, M. 2004. Drought-induced responses of photosynthesis and antioxidant metabolism in higher plants. Journal of Plant Physiology, 161 (11), 1189–1202. DOI: 10.1016/j.jplph.2004.01.013
- Rolland, F., Baena-Gonzalez, Sheen, J. 2006. Sugar sensing and signaling in plants: conserved and novel mechanisms. Annual Review of Plant Biology, 57, 675–709. DOI: 10.1146/annurev.ar-plant.57.032905.105441
- Saltykov, A.N., Razumny, V.V., Razumnaya, A.M. 2018. Natural and artificial resumption Pinus nigra J.F. Arnold subsp. pallasiana (lamb.) Holmboe in the conditions of foothill Crimea: features and differences. Ekosistemy, 14 (44), 31–41.
- Sin’kevich, M.S., Naraikina, N.V., Trunova, T.I. 2011. Processes hindering activation of lipid peroxidation in cold-tolerant plants under hypothermia. Russian Journal of Plant Physiology, 58 (6), 875–882.
- Summary for Policymakers. Climate change. 2014. Synthesis Report. JPCC, Geneva.
- Tarchevsky, I.A. 2001. Photosynthesis. Plant metabolism under stress. Selected Works (ed. A.N. Grechkina). FEN, Kazan, 9–102.
- Terlyga, N.S., Korshikov, I.I., Mazur, A.E. 2002. The assessment of Pinus pallasiana D. Don life state acording to the amount of needles in plants crown in plantations of Krivbass. Industrial Botany, 2, 15–18.
- Tomasella, M., Petrussa, E., Petruzzellis, F., Nardini, A., Casolo, V. 2020. The possible role of non-structural carbohydrates in the regulation of tree hydraulics. International Journal of Molecular Sciences, 21 (1), 144. DOI: 10.3390/ijms21010144
- Tsvetkova, N.N. 2013. Features of migration of organic and mineral substances and trace elements in forest-steppe ecosystems of Ukraine. Ltd. Stenli, Dnipropetrovsk.
- Tumanov, I.N. 1976. Physiology of hardening and frost resistance of plants. Nauka, Moscow.
- Ulyanovskaya, E.V., Nenko, N.I., Zaharova, M.V., Karavaeva, A.V. 2010. Physiological and biochemical features of resistance to drought of genotypes of the apple-tree of various ploidy. Fruit Growing and Viticulture of South Russia, 3 (2), 1–14.
- Van’t Hof, J. 1973. The regulation of cell division in higher plants. Brookhaven Symposia in Biology, 25, 152–165.
- Voron, V.P., Ivashinyuta, S.V. 2004. Anthropogenic changes of environment and forest transformations in techniques zone of factory “Volynzement”. Scientific Bulletin of UNFU, 14 (5), 162–172.
- Wang, A.-Y., Han, Sh.-J., Zhang, J.-H., Wang, M., Yin, X.-H., Fang, L.-D., Yang, D., Hao, G.-Y. 2018. The interaction between nonstructural carbohydrate reserves and xylem hydraulics in Korean pine trees across an altitudinal gradient. Tree Physiology, 38 (12), 1792–1804. DOI: 10.1093/treephys/tpy119
- Wang, X.Yu, Wang, Sh.le, Tang, Y., Zhou, W.M., Zhou, L., Zhong, Q.L., Dai, L.M., Yu, D.P. 2019. Characteristics of non-structural carbohydrate reserves of three dominant tree species in broadleaved Korean pine forest in Changbai Mountain, China. Chinese Journal of Applied Ecology, 30 (5), 1608–1614. DOI: 10.13287/j.1001-9332.201905.001
- Wiley, E., Rogers, B.J., Hodgkinson, R., Landhäusser, S.M. 2016. Nonstructural carbohydrate dynamics of lodge pole pine dying from mountain pine beetle attack. New Phytologist, 209 (2), 550–562. DOI: 10.1111/nph.13603
- Zeng, Y., Yu, J., Cang, J., Liu, L., Mu, Y., Wang, J., Zhang, D. 2011. Detection of sugar accumulation and expression levels of correlative key enzymes in winter wheat (Triticum aestivum) at low temperatures. Bioscience, Biotechnology and Biochemistry, 75 (4), 681–687. DOI: 10.1271/bbb.100813