[AKOPIAN, E. (1967): Effect of different types of ionizing radiation on the occurrence of chromosomal aberrations in pea. I. Postradiation recovery. Russ. J. Genet 3(5): 45-51.]Search in Google Scholar
[ALOV, I. A. (1965): Mechanisms of mitosis pathology. Vestn Akad Med Nauk SSSR. 1966; 21(11): 3-13.]Search in Google Scholar
[ARTYUKHOV, V. G. and V. N. KALAEV (2006): Cytogenetic indices of English oak (Quercus robur L.) seminal progeny subject to radioactive radiation in the Chernobyl nuclear disaster and growing on territories with different levels of anthropogenic contamination, pp. 247-264 in 20 Years after Chernobyl Accident: past, present and future, edited by E. B. BURLAKOVA, V. I. NAIDICH, Nova Science Publishers, Inc., New York.]Search in Google Scholar
[AXELROD, D. (1983): Biogeography of oaks in the Arcto- Tertiary province. Ann. Missouri Bot. Gard. 70: 629-657.]Search in Google Scholar
[BORZAN, K., M. IDZOJTIC and H. GUTTENBERGER (1996): Standardization of gymnosperm karyotypes using Picea omorika as an example. Forest Genetics 3(3): 127-136.]Search in Google Scholar
[BUTORINA, A. and N. EVSTRATOV (1996): The first detected case of amitosis in pine. Forest Genetics 3(3): 137-139.]Search in Google Scholar
[BUTORINA, A. and V. KALAEV (1998): Diversity of Cytological Characteristics in Oak Under Normal Conditions, pp. 46-48 in Diversity and Adaptation in Oak Species. Proceedings of a conference of IUFRO Working Party 2.08.05 held Oct. 12-17, Pennsylvania, U.S.A., Pennsylvania.]Search in Google Scholar
[CASTAGNEYROL, B., L. LAGACHE, B. GIFFARD, A. KREMER and H. JACTEL (2012): Genetic diversity increases insect herbivory on oak saplings. PloS One. DOI 10.1371/journal. pone.0044247.10.1371/journal.pone.0044247342941822937168]Search in Google Scholar
[CHELIDZE, P. V. and O. V. ZATCEPINA (1988): Morphofunctional classification of nucleoli. Uspekhi Sovr. Biol. 105(2): 252-267. (In Russian)]Search in Google Scholar
[CHEN, D., X. ZHANG, H. KANG, X. SUN, S. YIN, H. DU, N. YAMANAKA, W. GAPARE, H. WU and C. LIU (2012): Phylogeography of Quercus variabilis based on chloroplast DNA sequence in East Asia: multiple glacial refugia and Mainland-migrated island population. PloS One. DOI 10.1371/journal.pone.0047268.10.1371/journal.pone.0047268348036923115642]Search in Google Scholar
[CHYBIRKO, M. I. and J. I. STEPKIN (2009): Report on the epidemiological situation in the city of Voronezh in 2008.: Rospotrebnadzor in Voronezh region, Voronezh (in Russian).]Search in Google Scholar
[GALVAN, J., L. VALLEDOR, F. GONZALEZ, R. NAVARRO CERRILO and J. JORRIN-NOVO (2012): Proteomic analysis of Holm oak (Quecus ilex subsp. Ballota [Desf.] Samp.) pollen. J Proteomics 75(9): 2736-2744.]Search in Google Scholar
[GERAS’KIN, S. and D. VASIL’EV (2005): Assessment anthropogenic impact on the population of Pinus sylvestris L. by methods Bioindication in the area of enterprise storage of radioactive waste. Russ. J. Ecology 4: 275-285.]Search in Google Scholar
[KALAEV, V. (2000): Cytogenetic monitoring of environmental pollution using plant test - objects: Ph. D.. biol. Sciences. Voronezh. (In Russian)]Search in Google Scholar
[KALAEV, V., S. KARPOVA and V. ARTYUKHOV (2010): Cyto - genetic characteristics of weeping birch (Betula pendula Roth) seed progeny in different ecological conditions. Bioremediation, Biodiversity and Bioavailability, Special Issue 1 (Tree and Forest Biodiversity) 4: 77-83.]Search in Google Scholar
[KALASHNIK, N. and S. YASOVIEVA (2012): Analysis of meiotic chromosome aberrations in Siberian spruce (Picea obovata Ledeb.) under conditions of natural and technogenic stress. Russ. J. Ecology 43(6): 440-447.]Search in Google Scholar
[LAKIN, G. F. (1990): Biometrics. Vyshaia shkola. Moscow. LIC˘INA, V., M. F. AKS˘IC´, S. COLIC´ and G. ZEC (2013): A bioassessment of soil nickel genotoxic effect in orchard planted on rehabilitated coalmine overburden. Ecotoxicol Environ Saf. 98: 374-82.]Search in Google Scholar
[LUOMAJOKI, A. (1996): Adaptation of microsporogenesis of exotic conifers in Finland. Forest Genetics 3(3): 153-160.]Search in Google Scholar
[MIILLER, M. and D. GRILL (1996): Chromosomal aberrations in ozone-impacted spruce as a test of cytological damage in forest trees. Forest Genetics 3(3): 161-166.]Search in Google Scholar
[MILYUTIN, L., E. MURATOVA and A. LARIONOVA (2004): Conifer biodiversity in Mongolia and Adjacent Regions of Russia using morphological, karyological and genetical features. Eurasian J. of Forest Research 7(2): 59-66.]Search in Google Scholar
[MULLAGULOV, R., N. RED’KINA and J. IANBAEV (2008): Allosimic polimorfism English oak (Quercus robur (Fagaceae)) in isolated populations on the eastern boundary of the range. Vestnik Orenburgs State University 2: 107-110. (In Russian)]Search in Google Scholar
[MURATOVA, E., T. SEDELNIKOVA and A. PIMENOV et al. (2007): Karyological analysis of larch species from Siberia and the Far East of Russia. Forest Science and Technology 3(2): 89-94. (In Russian)10.1080/21580103.2007.9656323]Search in Google Scholar
[OUDALOVA, A. and S. GERAS’KIN (2012): The time dynamics and ecological genetic variation of cytogenetic effects in the Scots pine populations experiencing anthropogenic impact. Biology Bulletin Reviews 2(3): 254-267.10.1134/S207908641203005X]Search in Google Scholar
[PAVLICA, M., V. BESENDORFER, J. ROSA and D. PAPES CHEMOSPHERE (2000): The cytotoxic effect of wastewater from the phosphoric gypsum depot on common oak (Quercus robur l.) and shallot (Allium cepa var. Ascalonicum). Chemosphere 41(10): 1519-27.]Search in Google Scholar
[PRUS-GL⁄ OWACKI, W., E. CHUDZIN´SKA, A. WOJNICKAPOL⁄ TORAK, L. KOZACKI and K. FAGIEWICZ (2006): Effects of heavy metal pollution on genetic variation and cytological disturbances in the Pinus sylvestris L. population. J Appl Genet. 47(2): 99-108.10.1007/BF0319460716682749]Search in Google Scholar
[RAMIEZ-VALIENTE, J., D. SANCHEZ-GOMEZ, I. ARANDA and F. VALLADARES (2010): Phenotypic plasticity and local adaptation in leaf ecophysiological traits of 13 contrasting cork oak populations under different water availabilities. Tree Physiology 30(5): 618-627.10.1093/treephys/tpq01320357344]Search in Google Scholar
[RIBEIRO, T., A. BARÃO, W. VIEGAS and L. MORAIS-CECÍLI (2008): Molecular cytogenetics of forest trees. Cytogenet Genome Res. 120(3-4): 220-7.10.1159/00012107018504350]Search in Google Scholar
[SANS, J., M. MORENO and C. ALLIENDE (1984): The nucleolus and its regulation in meristems under two proliferative kinetics. Cytobios 41(163-164): 181-190.]Search in Google Scholar
[SILVESTRINI, M., C. A. PINTO-MAGLIO, M. I. ZUCCHI and F. A. DOS SANTOS (2013): Cytogenetics and characterization of microsatellite loci for a South American pioneer tree species, Croton floribundus. Genome 56(12): 743-51.10.1139/gen-2013-015924433210]Search in Google Scholar
[SIMAKOV, E. (1983): About postradiation restoration of cytogenetic damage in seedlings of different forms of seed potatoes. Radiobiology. Radioecology 23(5): 703-706.]Search in Google Scholar
[SOBOL’, M. (2001): The role of the nucleolus in the reactions of plant cells to the action of physical environmental factors. Cytology and genetics 35(3): 72-84.]Search in Google Scholar
[SENKEVICH, E. (2007): Cytogenetics of Scots pine and birch in the area Novovoronezh on issues environmental impact assessments. Ph. D.. biol. Sciences. Voronezh. (In Russian)]Search in Google Scholar
[ZHANG, Y. (2013): Molecular characterization and genetic structure of Quercus acutissima germplasm in China using microsatellites. Mol Biol Rep. 40(6): 4083-4090.10.1007/s11033-013-2486-623459930]Search in Google Scholar
