Selection evaluation of quantitative traits in seedlings from a hybrid combination between a seeded and seedless vine cultivar (VITIS VINIFERA L.)
Keywords:
model methodology; quantitative traits; selection; selection evaluation; vine seedlingsAbstract
A methodology has been applied for a complex selection evaluation by quantitative traits of seedlings from F1 progeny of a hybrid combination between a seeded and a seedless vine cultivar, which allows their classification by individual scale scores. A linear correlation exists between the phenotype characteristics of the studied seedlings and the environment. Seven elite hybrid forms have been selected possessing the optimal combination of the researched traits, the phenotype and genotype-environment effects. The obtained information on the selection value of the genotype of the separate plants makes it possible to determine suitable donors of commercially valuable ampelographic traits in sex hybridization, as well as to outline certain biological correlations in regard to the effect of additive genes interacting with the environment.
References
Ayala, F. J., & Kiger, J. A. (1984). Modern Genetics, Benjamin. Cummings, Menlo Park USA, 123-134.
Gerasimenko, V. F. (1978). Theory of express evaluation of the best genotypes in a plant population. Genetics of quantitative traits of agricultural plants.–M.: Nauka, 62–73 (Ru).
Gerus, L. V. (2016). Methodical aspects of evaluating grape breeding material. Varieties and protection of rights to varieties of roslin, 2(31), 22-26 (Uk).
Golodriga, P. Ya., & Troshin, L. P. (1978). Studies on the establishment of genotype-environment interactions in perennial plants. Genetics of quantitative traits of agricultural plants, 116-128 (Ru).
Kilchevsky, A. V., & Khotyleva, L. V. (1985). Method of assessment of adaptive capacity and stability of genotypes, differentiating capacity of the environment. Genetics, 21(9), 1481-1490 (Ru).
Kilchevsky, A. V., & Khotyleva, L. V. (1989). Genotype and environment in plant breeding. Science and Technology, 191 (Ru).
Lakin, G. F. (1990). Biometrics. Moscow: Vysshaya shkola, 351 (Ru).
Martynov, S. P., Krupnov, V. A., & Dragavtsev, V. A. (1978). Application of the Shrikandy method for evaluation of material in a breeding nursery. Genetics of quantitative traits of agricultural plants. Moscow, Nauka, 84-88 (Ru).
Perkins, J. M., & Jinks, J. L. (1971). Specificity of the interaction of genotypes with contrasting environments. Heredity, 26(3), 463.
Perkins, J. M., & Jinks, J. L. (1973). The assessment and specificity of environmental and genotype-environmental components of variability. Heredity, 30(2), 111.
Rashel, I. D. (1978). Possibility of determining the components of phenotypic variability of quantitative traits in plant papulations by the Shrikandy method. Genetics of quantitative traits of agricultural plants. Moscow: Nauka, 88-93 (Ru).
Roychev, V. (2012). Ampelography: Academic Publishing House at Agrarian University, 574 (Bg).
Rokitskyi, P. F. (1973). Biological statistics. - 3rd ed. - Minsk: Higher school, 328 (Ru).
Rone, M. J., & Kivits, E. (1978). Genetic equilibrium and parameters of selection of quantitative traits. Genetics of quantitative traits of agricultural plants. Moscow: Nauka, 150-163 (Ru).
Troshin, L. P., & Fedorov, Y. K. (1988). Biometric analysis of the gene pool of grapes / VNIIV and PP "Magarach". Yalta, 90 (Ru).
Fedin, M. A., Silis, D. Ya., & Smiryaev, A. V. (1980). Statistical methods of genetic analysis. Moscow: Kolos, 207 (Ru).
Khotyleva, L. V., & Tarutina, L. A. (1982). Interaction of genotype and environment: (Methods of assessment). Science and Technology, 112 (Ru).
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